BACKGROUND OF THE INVENTION
[0001] This invention is directed to test devices for determination of characteristics of
samples, unitized housings, and kits incorporating the test strips and housings, and
methods of determining the characteristics of samples using the test strips and housings.
[0002] WO-A-92/21977 describes a chromatographic assay device for detection and/or determination
of at least one analyte, the device comprising at least first and second opposable
components, at least one of the components including a chromatographic medium whereby
bringing said components into opposition causes at least one reactant involved in
the detection and/or determination of the analyte to be applied to the chromotographic
medium. The reactant may be located in a sample or in another liquid that is applied
to the chromatographic medium. Variations of that device provide for a number of analytes
to be detected by chromatographic methods including bidirectional chromatography.
The devices can be incorporated in test kits and assay methods are also described.
[0003] Among the many analytical systems used for detection and/or determination of analytes,
particularly analytes of biological interest, are chromatographic assay systems. Among
the analytes frequently assayed with such systems are: (1) hormones, such as human
chorionic gonadotropin (hCG), frequently assayed as a marker of human pregnancy: (2)
antigens, particularly antigens specific to bacterial, viral, and protozoan pathogens,
such as
Streptococcus, hepatitis virus,
Giardia, and feline leukemia virus (FeLV) ; (3) antibodies, particularly antibodies induced
as a result of infection with pathogens, such as antibody to the bacterium
Helicobacter pylori, to human immunodeficiency virus (HIV), or to feline immunodeficiency virus (FIV)
; (4) other proteins, such as hemoglobin, frequently assayed in determinations of
fecal occult blood, an early indicator of gastrointestinal disorders such as colon
cancer; (5) enzymes, such as aspartate aminotransferase, lactate dehydrogenase, alkaline
phosphatase, and glutamate dehydrogenase, frequently assayed as indicators of physiological
function and tissue damage; (6) drugs, both therapeutic drugs such as antibiotics,
tranquilizers, and anticonvulsants, and illegal drugs of abuse, such as cocaine, heroin,
and marijuana; (7) environmental pollutants such as pesticides and aromatic hydrocarbons;
and (8) vitamins.
[0004] Such chromatographic systems are frequently used by physicians, veterinarians, and
medical technicians for rapid in-office diagnosis and therapeutic monitoring of a
variety of conditions and disorders. They are also increasingly used by patients and
animal owners themselves for at-home monitoring of such conditions and disorders.
[0005] Among the most important of such systems are the "thin layer" systems in which a
solvent moves across a thin, flat, absorbent medium. Among the most important of tests
that can be performed with such thin layer systems are immunoassays, which depend
on the specific interaction between an antigen or hapten and a corresponding antibody.
The use of immunoassays as a means of testing for the presence and/or amount of clinically
important molecules has been known for some time. As early as 1956, J.M. Singer reported
the use of an immune-based latex agglutination test for detecting a factor associated
with rheumatoid arthritis (Singer et al.,
Am.J. Med. 22:888-892 (1956)).
[0006] Among the chromatographic techniques used in conjunction with immunoassays is a procedure
known as immunochromatography. In general, this technique uses a disclosing reagent
or particle that has been linked to an antibody to the molecule to be assayed, forming
a conjugate. This conjugate is then mixed with a specimen, and if the molecule to
be assayed is present in the specimen, the disclosing reagent-linked antibodies bind
to the molecule to be assayed, thereby giving an indication that the molecule to be
assayed is present. The disclosing reagent or particle can be identifiable by color,
magnetic properties, radioactivity, emission of light, specific reactivity with another
molecule, or another physical or chemical property. The specific reactions that are
employed vary with the nature of the molecule being assayed and the sample to be tested.
[0007] Immunochromatographic assays fall into two principal categories: "sandwich" and "competitive,"
acccrding to the nature of the antigen-antibody complex to be detected and the sequence
of reactions required to produce that complex. The antigen to be detected can itself
be an antibody, such as in serological assays for
H. pylori-specific antibody or for antibody to FIV. In such cases, the antibody to be detected
can be bound to a specific antigen. Alternatively, the antigen to be detected can
be detected indirectly by using a labeled second antibody that binds the first antibody
to the analyte to be detected.
[0008] In general, the sandwich immunochromatographic procedures call for mixing the sample
that may contain the analyte to be assayed with antibodies to the analyte. The antibodies
are mobile and typically are linked to a label or a disclosing agent, such as dyed
latex, a colloidal metal sol, or a radioisotope. This mixture is then applied to a
chromatographic medium containing a band or zone of immobilized antibody to the analyte
of interest. The chromatographic medium is often in a form of a strip resembling a
dipstick. When the complex of the molecule to be assayed and the labeled antibody
reaches the zone of the immobilized antibodies on the chromatographic medium, binding
occurs, and the bound labeled antibodies are localized at the zone. This indicates
the presence of the molecule to be assayed. This technique can be used to obtain quantitative
or semi-quantitative results.
[0009] Examples of sandwich immunoassays performed on test strips are described by U.S.
Patent No. 4,168,146 to Grubb et al. and U.S. Patent No. 4,366,241 to Tom et al.
[0010] In competitive immunoassays, the label is typically a labeled analyte or analyte
analog which competes for binding of an antibody with any unlabeled analyte present
in the sample. Competitive immunoassays are typically used for detection of analytes
such as haptens, each hapten being monovalent and capable of binding only one antibody
molecule. Examples of competitive immunoassay devices are those disclosed by U.S.
Patent No. 4,235,601 to Deutsch et al., U.S. Patent No. 4,442,204 to Liotta, and U.S.
Patent No. 5,208,535 to Buechler et al.
[0011] Although useful, currently available chromatographic techniques using test strips
have a number of drawbacks. Many samples, such as fecal samples, contain particulate
matter that can clog the pores of the chromatographic medium, greatly hindering the
immunochromatographic process. Other samples, such as blood, contain cells and colored
components that make it difficult to read the test. Even if the sample does not create
interference, it is frequently difficult with existing chromatograph test devices
to apply the sample uniformly to the chromatographic medium. This is highly desirable
to ensure that the sample front moves uniformly through the chromatographic medium
to insure that the sample reaches the area where binding is to occur in a uniform,
straight-line matter. Other problems exist with currently-available test strips because
of the nature of the sample to be assayed or the assay to be carried out. In many
currently-available test strips, the time of passage of the specimen, from the point
of application to passage past the specific capture band on the solid phase, frequently
results in an undesirable time delay in obtaining results. In addition, variable specimen
and reagents may be lost in the dead volume of the elements in the path to the capture
zone.
[0012] With currently-available designs, it is also impractical to perform washing steps
which are frequently desirable to improve sensitivity and reduce background. Also,
it is difficult, and in many cases impossible, to carry out preincubation steps within
the device.
[0013] Sample preparation and waste generation are responsible for other problems with currently
available devices and techniques for immunochromatography. The increased prevalence
of diseases spread by infected blood and blood fractions, such as AIDS and hepatitis,
has exacerbated these problems. It is rarely possible to apply a sample (such as feces)
or a sampling device (such as a throat swab) directly to the chromatographic medium.
Several extraction and pretreatment reactions are usually required before the sample
can be applied to the chromatographic medium. These reactions are typically carried
out by the physician, veterinarian, or technicians performing the test in several
small vessels, such as test tubes or microfuge tubes requiring the use of transfer
devices such as pipettes. Each of these devices is then contaminated and must be disposed
of using special precautions so that workers or people who may inadvertently come
into contact with the waste do not become contaminated.
[0014] Still another limitation in chromatographic devices currently available for use by
the physician, veterinarian, or technician is their inability to perform two-directional
or two-dimensional chromatography. These techniques have long been known to be powerful
analytical tools, but their complexity relative to simple unidirectional chromatography
has made it difficult to apply them to test strip devices in the physician's office
or a clinical laboratory.
[0015] Additionally, currently available test devices cannot perform two independent assays
for two different analytes on the same test strip. One particular application of this
would be the ability to perform a unidirectional sandwich assay and a bidirectional
serological assay for an antibody as an analyte in the same test strip. Because the
antibody that binds to a particular antigen is only a small fraction of the total
antibody molecules present in the serum, the use of a unidirectional assay for an
analyte that is an antibody is generally unsatisfactory, because the detection reagent
will bind to many other antibody molecules on the test strip other than the antibody
for the desired antigen, thus creating an unacceptably high background. This is true
even if a second antibody specific for a class or subclass is used, because many individual
antibodies belong to that class or subclass.
[0016] The ability to perform two such immunoassays on the single test strip is desirable
when it is desired to determine the existence or non-existence of two specific diseases
or conditions in the same sample. Alternatively, it can be desirable to perform assays
for the simultaneous detection of both an antigen that is associated with a viral
or bacterial pathogen and an antibody that is associated with the immunological response
of the body to that pathogen in the same sample. An example is HIV virus, where a
protein antigen known as p24 can be found in infected patients, while an antibody
to the virus can also be found in many patients. It can be desirable to assay both
of these in order to help determine the clinical status of the patient.
[0017] Accordingly, there is a need for an improved assay device capable of handling a broad
range of chromatographic assays, including the ability to assay for two separate analytes
in the same test strip. Such a device should be capable of receiving a possibly contaminated
sample or a sample preparation device directly so as to eliminate the need for extraction
vessels and transfer devices. Such a device, preferably in the form of a test strip,
should also be capable of performing immunochromatographic assays on colored samples
or samples containing particulates without interference and should be able to deliver
the sample to the chromatographic medium uniformly and evenly to improve accuracy
and precision of the tests. Moveover, such a test strip should minimize the time delay
experienced in the performance of the assay and also minimize the dead volume in order
to provide maximum economy in the use of samples and reagents.
SUMMARY
[0018] An assay device according to the present invention as defined by the claims can perform
at least two assays on the same test strip simultaneously, an immunological assay
for detection of an antigen and a serological assay for detection of an antibody.
[0019] In general, such a device can comprise:
(1) a first opposable component including at least one chromatographic medium having
a specific binding partner to the first analyte and a specific binding partner to
the second analyte immobilized thereto in separate, discrete, non-overlapping zones;
and
(2) a second opposable component including an absorber.
The first and second opposable components are configured such that bringing the first
and second opposable components into opposition causes the absorber to come into operable
contact with at least one chromatographic medium. This results in the zone containing
the specific binding partner to the first analyte being functionally divided from
the zone containing the specific binding partner to the second analyte so that both
analytes can be detected.
[0020] Typically, detection of the first analyte occurs by the formation of a ternary complex
involving the first analyte, a labeled specific binding partner to the first analyte,
and the immobilized specific binding partner to the first analyte. Detection of the
second analyte occurs by formation of a ternary complex involving the second analyte,
a detection reagent for the second analyte, and the immobilized specific binding partner
to the second analyte.
[0021] The first analyte can be an antigen, while the second analyte can be an antibody.
[0022] The chromatographic medium can be divided into two sectors, a first sector containing
the specific binding partner to the first analyte and a second sector containing the
specific binding partner to the second analyte.
[0023] The second opposable component can further include at least one applicator. The second
opposable component can include two applicators, an applicator containing a labeled
specific binding partner for the first analyte and an applicator containing a detection
reagent for the second analyte. The first and second opposable components can be configured
such that when the first and second opposable components are brought into opposition,
the absorber is in operable contact with the chromatographic medium such that the
device performs a unidirectional chromatographic specific binding assay for the first
analyte and a bidirectional chromatographic specific binding assay for the second
analyte.
[0024] A method for the detection and/or determination of at least two analytes in an aqueous
sample, using this assay device, comprises the steps of:
(1) applying a first aliquot of the sample to the first applicator of the assay device
as claimed in claim 5;
(2) allowing the sample to migrate from the first applicator through the conjugate
zone and then through at least the portion of the chromatographic medium including
the specific binding partner for the first analyte;
(3) bringing the first and second opposable components into opposition to cause the
second applicator to come into contact with the conductor and to cause the absorber
to come into contact with the chromatographic medium to draw fluid from the conductor
through the portion of the chromatographic medium including the specific binding partner
for the second analyte from the conductor to the absorber; and
(4) detecting and/or determining the two analytes in the test sample by observing
and/or measuring the labeled specific binding partner to the first analyte bound at
the specific binding partner for the first analyte immobilized on the chromatographic
medium and the detection reagent for the second analyte bound to the specific binding
partner for the second analyte immobilized on the chromatographic medium.
[0025] The labeled specific binding partner for the first analyte and the detection reagent
for the second analyte can be each labeled with a visually detectable label. In this
case, the step of observing and/or measuring the labeled specific binding partner
for the first analyte and the detection reagent for the second analyte is performed
visually.
[0026] A method for the detection and/or determination of at least two analytes in an aqueous
sample using the assay device of claim 12 comprises the steps of:
(1) applying a first aqueous liquid to the second applicator of the assay device;
(2) applying a first aliquot of the sample to the first applicator;
(3) applying a second aliquot of the sample to the sample preparation zone;
(4) allowing the second aliquot of the sample applied to the sample preparation zone
to migrate through at least a portion of the chromatographic medium including the
specific binding partner for the second analyte;
(5) bringing the first and second opposable components into opposition to cause the
absorber to come into contact with the sample preparation zone and with the chromatographic
medium, the first applicator to come into contact with the first conductor, and the
second applicator to come into contact with the second conductor;
(6) allowing the first aliquot of the sample and the resolubilized labeled specific
binding partner to the first analyte to migrate through at least a portion of the
chromatographic medium containing the immobilized specific binding partner to the
first analyte and allowing the resolubilized detection reagent for the second analyte
to migrate through at least a portion of the chromatographic medium containing the
immobilized specific binding partner to the second analyte; and
(7) detecting and/or determining the first analyte and the second analyte by observing
and/or measuring the labeled specific binding partner to the first analyte bound to
the zone of the immobilized specific binding partner to the first analyte and the
detection reagent bound to the zone of the immobilized specific binding partner for
the second analyte.
BRIEF DESCRIPTION OF THE DRAWINGS
[0027] These and other features, aspects, and advantages of the present invention will become
better understood with reference to the following description, appended claims, and
accompanying drawings where:
Figure 1A is a depiction of an embodiment of an assay device according to the present
invention in which the first opposable component has a first applicator and the second
opposable component has a second applicator, shown in open position;
Figure 1B is a sectional rear view of the device of Figure 1A with the components
in opposition;
Figure 2A is a depiction of a first version of a second embodiment of an assay device
according to the present invention with one applicator and one chromatographic medium
divided into sectors, shown in open position;
Figure 2B is a sectional rear view of the device of Figure 2A with the components
in opposition;
Figure 3A is a depiction of a second version of the second embodiment of an assay
device according to the present invention with one applicator bridging two chromatographic
media, shown in open position;
Figure 3B is a sectional rear view of the device of Figure 3A with the components
in opposition;
Figure 4 is a depiction of an assay device constructed according to the present invention
for the detection of anti-rubella antibody and human chorionic gonadotropin, shown
in open form; and
Figure 5 is a depiction of the assay device of Figure 4 after closing of the opposable
components, showing the lines indicating the presence of the analytes through the
windows of the device.
DESCRIPTION
Definitions
[0028] In the context of this disclosure, the following terms are defined as follows unless
otherwise indicated:
[0029] Specific Binding Partner: A member of a pair of molecules that interact by means
of specific noncovalent interactions that depend on the three-dimensional structures
of the molecules involved. Typical pairs of specific binding partners include antigen-antibody,
hapten-antibody, hormone-receptor, nucleic acid strand-complementary nucleic acid
strand, substrate-enzyme, inhibitor-enzyme, carbohydrate-lectin, biotin-avidin, and
virus-cellular receptor.
[0030] Operable Contact: Two solid components are in operable contact when they are in contact,
either directly or indirectly, in such a manner that an aqueous liquid can flow from
one of the two components to the other substantially uninterruptedly, by capillarity
or otherwise. "Direct contact" means that the two elements are in physical contact,
such as edge-to-edge or front-to-back. Typically, when two components are in direct
contact, they are overlapped with an overlap of about 0.5 to about 3 mm. However,
the components can be placed with abutting edges. "Indirect contact" means that the
two elements are not in physical contact, but are bridged by one or more conductors.
[0031] Analyte: The term "analyte" includes both the actual molecule to be assayed and analogues
and derivatives thereof when such analogues and derivatives bind another molecule
used in the assay in a manner substantially equivalent to that of the analyte itself.
[0032] Antibody: The term "antibody" includes both intact antibody molecules of the appropriate
specificity and antibody fragments (including Fab, F(ab'), and F(ab')
2 fragments) as well as chemically modified intact antibody molecules and antibody
fragments, including hybrid antibodies assembled by
in vitro reassociation of subunits. Unless otherwise specified, the term "antibody" includes
both polyclonal and monoclonal antibodies.
[0033] Secondary Specific Binding Partner: An additional specific binding partner that binds
to a member of a pair of specific binding partners when the pair of specific binding
partners is interacting is designated a secondary specific binding partner. However,
the binding of the secondary specific binding partner to a member of the pair of specific
binding partners need not occur only when the pair of specific binding partners interacts.
For example, a pair of specific binding partners can comprise
Giardia antigen and rabbit anti-
Giardia antibody. In that case, the secondary specific binding partner can be goat anti-rabbit
IgG antibody, which will bind to the rabbit anti-
Giardia antibody. The binding of the goat anti-rabbit IgG antibody to the rabbit anti-
Giardia antibody does not require binding of the rabbit anti-
Giardia antibody to the
Giardia antigen. The secondary specific binding partner can be specific for the species,
class, or subclass of an antibody specific binding partner to which it binds. Alternatively,
when one of the specific binding partners is labeled with biotin, the secondary specific
binding partner can comprise a molecule conjugated to avidin to make use of the specificity
and tight binding of the biotin-avidin link.
I. PRINCIPLES OF OPERATION OF INTERRUPTED-FLOW ASSAY DEVICES
[0034] In many cases, it is desirable to perform multiple assays in a single test strip.
This can be done in testing for a number of conditions or for multiple viruses. Although
this can be done on multiplex devices that have multiple chromatographic media, this
is not practical when one of the assays must be performed in a bidirectional mode
while another assay is performed in a unidirectional mode. This is typically the case
if one of the assays is for an antigen or a hapten and the other assay is for an antibody,
i.e., a serological assay. For example, it can be useful to test for an antibody to
human immunodeficiency virus (HIV) and a HIV-specific antigen, such as a protein produced
by the virus designated p24. Another example is testing for feline leukemia virus
(FeLV) and antibody to feline immunodeficiency virus (FIV) in the same serum sample.
[0035] While assays of antigens and haptens can be carried out in either a one-directional
or a two-directional format, it is strongly preferred to perform serological assays
of antibodies in a two-directional format. This is because the analyte to be detected
is normally detected on the basis of a specificity unrelated to the specificity that
causes the antibody to bind to its corresponding antigen. The presence of other antibodies
with other specificities would therefore interfere with that detection step. For example,
if antibody to FIV is being assayed, and the detection reagent is a labeled rabbit
antibody to cat immunoglobulins, all cat immunoglobulins present on the test strip
will bind the detection reagent. This generally creates unacceptably high backgrounds
leading to low sensitivity and irreproducibility.
[0036] To overcome these problems, I have developed assay devices that split flow to perform
multiple assays on a single test strip. These devices operate by performing two tests
on the same strip, either by providing for a flow outward from a centrally located
sample preparation zone for one of the assays while applying a second sample on a
separate applicator, or by interrupting the flow of the sample by an absorber as discussed
below to allow for flow in the second direction.
A. Principles of Operation
[0037] Assay devices according to the present invention operate by dividing the flow in
a chromatographic medium so that the two assays on separate analytes can be performed.
The chromatographic medium is incorporated in an assay device that includes two or
more opposable components that can be brought into opposition to apply pressure to
the chromatographic medium and to other fluid-containing or fluid absorbing-elements
present in the assay device. This can apply an absorber or absorbers to the chromatographic
medium, or can apply an applicator or applicators to it. The absorbers and/or applicators
are located on an opposable component different than the opposable component on which
the chromatographic medium is located. This sequence of operation results in the flow
of the reagents in a predetermined pattern to perform two assays in one test device.
[0038] In one embodiment of the present invention, a single sample is used, and during chromatography
in the first direction, the components are opposed and the flow is interrupted in
the first direction at a point of the chromatographic medium removed from its ends.
Simultaneously, an applicator is placed in contact with the chromatographic medium
to apply a detection reagent, which flows in the second direction, i.e., opposite
from the direction of flow of the sample. Thus, one-directional and two-directional
flow are achieved in the same chromatographic medium for assay of two analytes simultaneously.
[0039] In the second embodiment, a sample preparation zone is located between two sectors
of a chromatographic medium. The separation between two sectors can either be structural
or functional; i.e., the chromatographic medium can be physically continuous or it
can be divided. In this embodiment, the flow outward from the sample preparation zone
is used for one of the assays by applying a detection reagent to the chromatographic
medium, which flows through it in a direction opposite to the flow of the sample,
thus performing a bidirectional assay. The other assay is performed by adding a second
sample and a labeled specific binding partner for the analyte to the chromatographic
medium and allowing them to flow through the chromatographic medium in the same direction.
This direction is opposite to the direction of the sample flow in the first assay.
[0040] In general, an assay device according to the present invention comprises:
(1) a first opposable component including at least one chromatographic medium having
a specific binding partner to the first analyte and a specific binding partner to
the second analyte immobilized thereto in separate, discrete, non-overlapping zones;
and
(2) a second opposable component including an absorber.
The first and second opposable components are configured such that bringing the first
and second opposable components into opposition causes the absorber to come into operable
contact with at least one chromatographic medium so that the zone containing the specific
binding partner to the first analyte is functionally divided from the zone containing
the specific binding partner to the second analyte so that both analytes can be detected.
[0041] Typically, the detection of the first analyte occurs by formation of a ternary complex
involving the first analyte, a labeled specific binding partner to the first analyte,
and the immobilized specific binding partner to the first analyte. The detection of
the second analyte occurs by formation of a ternary complex involving the second analyte,
a detection reagent for the second analyte, and the immobilized specific binding partner
to the second analyte.
[0042] The second opposable component can include at least one applicator. Typically, the
second opposable component includes at least two applicators, an applicator containing
a labeled specific binding partner for the first analyte and an applicator containing
a detection reagent for the second analyte.
[0043] Typically, the first and second opposable components are configured such that when
the first and second opposable components are brought into opposition, the absorber
is in operable contact with the chromatographic medium. This causes the device to
perform a one-dimensional chromatographic specific binding assay for the first analyte
and a two-dimensional specific binding assay for the second analyte.
[0044] In general, a first embodiment of the assay device comprises:
(1) a first opposable component including:
(a) a chromatographic medium having thereon in discrete, separated, non-overlapping
zones:
(i) a specific binding partner for a first analyte; and
(ii) a specific binding partner for a second analyte; and
(b) a first applicator to apply a sample and a labeled specific binding partner to
the first analyte to the chromatographic medium; and
(2) a second opposable component including:
(a) a second applicator to apply a detection reagent for the second analyte to the
chromatographic medium; and
(b) an absorber, which, when the first and second opposable components are brought
into opposition, is in operable contact with the chromatographic medium and functionally
divides the chromatographic medium into two sectors, the first sector for the detection
of the first analyte and a second sector for the detection of the second analyte.
[0045] In general, a second embodiment of the assay device comprises:
(1) a first opposable component including:
(a) at least one chromatographic medium having thereon in discrete, separated, non-overlapping
zones:
(i) a specific binding partner for a first analyte; and
(ii) a specific binding partner for a second analyte;
(b) a sample preparation zone separating the specific binding partner for the first
analyte and the specific binding partner for the second analyte on the at least one
chromatographic medium; and
(2) a second opposable component including:
(a) an absorber;
(b) a first applicator; and
(c) a second applicator.
[0046] The first and second opposable components are configured such that when the first
and second opposable components are brought into opposition: (1) the first applicator
applies a labeled specific binding partner to the first zone of the chromatographic
medium; (2) the second applicator applies a detection reagent for the second analyte
to the second zone of the chromatographic medium; and (3) the absorber functionally
divides the first zone from the second zone so that the labeled specific binding partner
to the first analyte is substantially excluded from the second zone and the detection
reagent for the second analyte is substantially excluded from the first zone.
B. Elements Common to Devices According to the Present Invention
[0047] A number of elements are common to assay devices according to the present invention
and are discussed here for convenience.
1. The Chromatographic Medium
[0048] The chromatographic medium is a strip. Typically, the strip is substantially planar,
although this is not required in all applications. It is typically rectangular, having
first and second ends and first and second surfaces. Throughout this description,
the term "first end" refers either to the end to which sample is first supplied to
the chromatographic medium or to the end that is closer to the point at which detection
of the first analyte occurs. The term "second end" applies to the opposite end of
the chromatographic medium. The chromatographic medium is composed of a material or
materials suitable as a medium for thin layer chromatography of analyte and analyte-antibody
conjugates, such as nitrocellulose, nylon, rayon, cellulose, paper, or silica. Preferably,
the chromatographic medium is nitrocellulose. The chromatographic medium can be pretreated
or modified as needed. Typically, the chromatographic medium is translucent, so that
colored bands appearing on it can be viewed from either side. The chromatographic
medium can be composed of two or more sectors with different properties, such as thickness
or porosity. For example, if the first analyte is an antigen and the second analyte
is an antibody in a serological assay, it can be preferred to have one portion of
the chromatographic medium be nitrocellulose with a porosity of 5 µm, for assay of
the analyte, and the second sector have a porosity of 12 µm, for efficient assay of
an antibody in serum. Other variations of the chromatographic medium can be used.
For example, it may be possible to treat one portion of the medium but not the other
with a reagent that facilitates the assay.
2. Absorbers
[0049] In a number of devices according to the present invention, an absorber is in operable
contact with a portion of the chromatographic medium at some stage of the assay. The
absorber can be made of any bibulous material that holds an aqueous liquid sufficiently
so liquid can be drawn through the chromatographic medium and accumulated in the absorber.
Typical materials include, but are not limited to, filter paper.
3. Other Fluid-Carrying Elements
[0050] As described below, in particular devices according to the present invention, other
fluid-carrying elements can be employed as sample preparation zones, applicators,
conjugate zones, and/or conductors. These elements are prepared of hydrophilic media
that pass aqueous liquids without substantially absorbing them. Such materials are
well-known in the art. In some cases, these elements can have incorporated therein
a component in dry form that can be resolubilized by addition of a aqueous liquid
to the element. The aqueous liquid can be either the sample migrating through the
element or another separate aqueous liquid.
4. Opposable Components
[0051] Assay devices according to the present invention comprise two or more opposable components,
typically two opposable components. The bodies of the opposable components are preferably
made of laminated cardboard that is sufficiently impervious to moisture to contain
the liquids involved in the performance of the assay carried out by the device. Other
cellulose-based materials, such as paperboard or solid bleached sulfite (SBS) can
also be used. Alternatively, the bodies of the opposable components can be made of
plastic that is impervious to moisture. A suitable plastic is a polycarbonate plastic
such as Lexan™.
[0052] Typically, the first and second opposable components are substantially planar.
[0053] The opposable components are connected so that when they are opposed, the elements
on their surfaces are reproducibly brought into contact. Typically, they are joined
by a hinge, preferably made of a material impermeable to aqueous liquids, such as
a plastic that can be compatibly joined with or is the same as the material used for
the first and second opposable components.
[0054] The device also has means for opposing the opposable components and applying pressure
thereto. The pressure applied is sufficient to transfer fluid from one opposable component
to another opposable component in a direction substantially normal to the opposable
components so that the fluid is applied to the chromatographic medium for detection
and/or determination of the analyte thereon. The pressure also drives fluid through
the chromatographic medium to accelerate the process of chromatography, giving a detectable
result in less time. Additionally, the pressure can make possible the performance
of steps, such as extraction steps, in the device, and can be used to remove excess
fluid from the chromatographic medium by absorbers to reduce the background of the
assays. The pressure is generated by placing the opposable components into opposition
and maintained by holding the components into opposition by engagers such as locks
or clasps.
II. ASSAY DEVICES
A. Device With Undivided Chromatographic Medium Employing Interrupted Flow in One Direction
[0055] One embodiment of the present invention is a device with a undivided chromatographic
medium employing interrupted flow in one direction. In the operation of this device,
bringing the first and second opposable components together causes an absorber to
come into operable contact with a portion of the chromatographic medium. This reverses
flow for one of the assays while allowing flow to continue in the original direction
for the other assay. Thus, this device performs a unidirectional immunochromatographic
assay and a bidirectional immunochromatographic assay in the same assay device. As
used herein, the term "immunochromatographic" includes not only assays employing antibodies,
but also assays employing other proteins with specific binding affinity for analytes,
because the general principles of their operation is the same.
[0056] This embodiment of an assay device according to the present invention comprises:
(1) a first opposable component including:
(a) a chromatographic medium having a first end, a second end, and first and second
surfaces, the chromatographic medium having thereon in discrete, separated, non-overlapping
zones:
(i) a specific binding partner for a first analyte;
(ii) a specific binding partner for a second analyte;
(b) a conjugate zone containing a specific binding partner to the first analyte labeled
with a first detectable label, the specific binding partner being present in a form
that can be resolubilized by the addition of an aqueous liquid to the conjugate zone,
the conjugate zone being in operable contact with the first end of the chromatographic
medium;
(c) a first applicator in operable contact with the conjugate zone, the conjugate
zone bridging the first applicator and the first end of the chromatographic medium;
and
(d) a conductor in operable contact with the second end of the chromatographic medium;
and
(2) a second opposable component including:
(a) an absorber; and
(b) a second applicator separated from the absorber, the second applicator containing
a detection reagent for the second analyte in a form that can be resolubilized by
the addition of an aqueous liquid to the second applicator.
[0057] The first and second opposable components are configured so that bringing the first
and second opposable components into opposition: (1) causes the second applicator
to come into contact with the conductor; and (2) causes the absorber to come into
contact with the chromatographic medium at a point between the specific binding partner
for the first analyte and the specific binding partner for the second analyte. This
results in the absorbers drawing fluid from the first applicator through a portion
of the chromatographic medium from the first end of the chromatographic medium to
the specific binding partner for the first analyte, and simultaneously drawing fluid
from the second applicator through a portion of the chromatographic medium from the
second end of the chromatographic medium to the specific binding partner for the second
analyte.
[0058] In other words, the assay for the first analyte is unidirectional and remains unidirectional
after the applicator is applied. This assay is unidirectional because the sample and
the labeled specific binding partner for the first analyte move in the same direction.
However, the assay for the second analyte is bidirectional because the sample moves
in one direction and the detection reagent for the second analyte moves in the opposite
direction. In this embodiment, the flow of sample for the assay of the second analyte
is cut off when the absorber is placed in operable contact with the chromatographic
medium. Typically, the second analyte is an antibody produced by a mammalian species
in response to an antigen and the detection reagent for the second analyte is a labeled
antibody that binds the second analyte on the basis of a specificity unrelated to
the specificity by which the second analyte binds its corresponding antigen. Where
the second analyte is an antibody, the specific binding partner bound to the chromatographic
medium is typically an antigen or an antigen analogue for which the antibody that
is the second analyte has specific binding affinity. For example, if the second analyte
is antibody to feline immunodeficiency virus (FIV), the specific binding partner bound
to the chromatographic medium can be the protein antigen of the FIV virus against
which the antibody is directed. The detection reagent can be labeled goat anti-cat
IgG. The detection reagent can also detect the antibody that is the second analyte
on the basis of a specificity such as a subclass specificity. For example, if it is
desired to detect an antibody that is a human IgG1 immunoglobulin, the detection reagent
can be a labeled goat anti-human IgG1 antibody produced by immunizing the goat with
a purified human IgGl immunoglobulin and then absorbing out determinants common to
other subclasses. Such techniques are well known in the art of immunochemistry and
need not be described further here.
[0059] Typically, when the second analyte is an antibody, the first analyte is an antigen.
[0060] The chromatographic medium can comprise two sectors of different porosities when
the first analyte is an antigen and the second analyte is an antibody. The first sector
includes the specific binding partner for the first analyte and has a porosity suitable
for the detection of the first analyte as an antigen. The second sector includes the
specific binding partner for the second analyte and has a porosity suitable for the
detection of the analyte as an antibody in a serological sample. Typically, the diameter
of the pores in the second sector is greater than the diameter of the pores in the
first sector. For example, for the detection of FeLV and antibody to FIV, the first
sector can be nitrocellulose with a porosity of 5 µm and the second sector can be
nitrocellulose with a porosity of 12 µm.
[0061] This device is depicted in Figures 1A and 1B. Figure 1A shows the device in its open
position, while Figure 1B is a sectional rear view of the device, showing details
of the components in opposition.
[0062] The device 10 has first and second opposable components 12 and 14, joined by a hinge
16. The first and second opposable components 12 and 14 have engagers such as locks
18 and 20 that hold the opposable components together. The first and second opposable
components 12 and 14 also have a ridge or gasket 22 surrounding them to prevent the
escape of samples or reagents. The first opposable component 12 includes a chromatographic
medium 24 with first and second ends 26 and 28 and first and second surfaces 30 and
32. The chromatographic medium 24 has thereon in discrete, separated, non-overlapping
zones, a specific binding partner for the first analyte 34 and a specific binding
partner for the second analyte 36. Preferably, the chromatographic medium 24 also
has thereon an area of a resolubilizable dye 38, and a control zone 40 that binds
the detection reagent for the second analyte. Marked on or immediately adjacent to
the chromatographic medium 24 is a limit line 42.
[0063] The first opposable component 12 also includes a conjugate zone 44 that contains
a specific binding partner for the first analyte labeled with a detectable label in
resolubilizable form. The first opposable component 12 also includes a first applicator
46 for application of the sample. The first applicator 46 is in operable contact with
the conjugate zone 44, so that the conjugate zone 44 bridges the first applicator
46 and the first end 26 of the chromatographic medium 24. The first opposable component
12 also includes a conductor 48 in operable contact with the second end 28 of the
chromatographic medium 24.
[0064] The second opposable component 14 includes an absorber 50 and a second applicator
52 separated from the absorber 50. The second applicator 52 contains a detection reagent
for the second analyte in a form that can be resolubilized by the addition of an aqueous
liquid to the second applicator 52. Preferably, the second opposable component 14
also includes a first window 54 and a second window 56. The first window 54 allows
viewing of the specific binding partner for the first analyte 34 when the first and
second opposable components 12 and 14 are brought into opposition. The second window
56 allows viewing of the specific binding partner for the second analyte 36 when the
first and second opposable components 12 and 14 are brought into opposition.
[0065] Bringing the first and second opposable components 12 and 14 into opposition causes
the second applicator 52 to come into contact with the conductor 48 and causes the
absorber 50 to come into contact with the first surface 30 of the chromatographic
medium 24 at a point between the specific binding partner for the first analyte 34
and the specific binding partner for the second analyte 36. This causes the absorber
50 to draw fluid from the first applicator 46 through a portion of the chromatographic
medium 24 from the first end 26 of the chromatographic medium 24 to the specific binding
partner for the first analyte 34, and simultaneously draws fluid from the second applicator
52 through a portion of the chromatographic medium 24 from the second end 28 of the
chromatographic medium 24 to the specific binding partner for the second analyte 36.
[0066] In use, a sample is applied to the first applicator 46 and allowed to migrate from
the first applicator 46 through the conjugate zone 44 and then through at least a
portion of the chromatographic medium 24 including the specific binding partner for
the first analyte 36. Preferably, the sample moves through the area of the resolubilizable
dye 36 and the control zone 40. An aqueous liquid is added to resolubilize the detection
reagent in the second applicator 52. When the resolubilized dye and the sample reach
the limit line 42, the first and second opposable components 12 and 14 are brought
into opposition to apply the second applicator 52 to the conductor 48 and to apply
the absorber 50 to the first surface 30 of the chromatographic medium 24. This reverses
the flow for the second assay so that the detection reagent for the second analyte
is drawn back across the chromatographic medium 24 in the opposite direction to the
direction that the sample migrated through the chromatographic medium 24. This performs
a bidirectional immunochromatographic assay for the second analyte. At the same time,
migration can continue from the sample in the first applicator through the conjugate
zone 44 to the absorber 50 in operable contact with the chromatographic medium 24.
This accomplishes a unidirectional immunochromatographic assay for the first analyte.
[0067] Typically, the chromatographic medium has dimensions of about 0.5 inch to about 1
inch (about 1.27 cm to about 2.54 cm) for its length and of about 0.125 inch to about
0.375 inch (about 0.318 cm to about 0.953 cm) for its width.
[0068] Typically, the sample volume is from about 25 to about 250 µl, more typically about
100 µl. Typically, to achieve results, the time from the application of the sample
until the sample reaches the limit line is about 40 to 60 seconds. The total time
for performance of the assay is typically about 1 to 2 minutes. Typically, the assay
is performed at room temperature, although it can be performed at 4°C or up to 37°C
or higher in some cases, depending upon the nature of the analyte, the chromatographic
medium, and the specific binding partners. In some cases, performing the assay at
a lower temperature may be desirable to limit degradation of the sample or of a specific
binding partner, while in other cases, performing the assay at a higher temperature
with suitable analytes and specific binding partners may speed up the assay.
B. Devices with Chromatographic Medium Divided into Sectors
[0069] In another embodiment of the present invention a sample preparation zone is located
between two sectors of the chromatographic medium, either with a continuous or a divided
chromatographic medium. In this embodiment, as described above, the sample flowing
from the sample preparation zone is used to perform a bidirectional immunochromatographic
assay, typically a serological assay. A separate aliquot of the sample is applied
to the chromatographic medium for the performance of a unidirectional immunochromatographic
assay.
1. Device with Sample Preparation Zone in Operable Contact with Chromatographic Medium
[0070] One version of this embodiment has a sample preparation zone in operable contact
with the chromatographic medium. In this device, the chromatographic medium is continuous
in structure, although it is divided functionally because flow occurs from one end
of the sample preparation zone outward toward one end of the chromatographic medium.
The other end of the sample preparation zone is not in operable contact with the chromatographic
medium until the first and second opposable components are brought into opposition
and an absorber is brought into operable contact with the sample preparation zone
and chromatographic medium to withdraw fluid from them.
[0071] This device comprises:
(1) a first opposable component including:
(a) a chromatographic medium having a first end and a second end, the chromatographic
medium having thereon in discrete, separated, non-overlapping zones:
(i) a specific binding partner for a first analyte; and
(ii) a specific binding partner for a second analyte;
(b) a first conductor in operable conduct with the first end of the chromatographic
medium;
(c) a second conductor in operable contact with the second end of the chromatographic
medium; and
(d) a sample preparation zone in operable contact with a portion of the chromatographic
medium between the specific binding partner for the first analyte and the specific
binding partner for the second analyte; and
(2) a second opposable component including:
(a) an absorber;
(b) a first applicator separated from the absorber and containing a specific binding
partner to the first analyte labeled with a detectable label in a form that can be
resolubilized by the addition of an aqueous liquid to the first applicator; and
(c) a second applicator separated from the absorber and containing a detection reagent
for the second analyte in resolubilizable form.
[0072] In this device, the first and second opposable component are configured so that bringing
the first and second opposable components into opposition: (1) causes the absorber
to come into contact with the sample preparation zone and with the chromatographic
medium so that the sample preparation zone and the chromatographic medium are brought
into indirect contact; (2) causes the first applicator to come into operable contact
with the first conductor; and (3) causes the second applicator to come into operable
contact with the second conductor. Thus, the absorber draws fluid from the first and
second applicators through the chromatographic medium toward the absorber. This performs
a unidirectional assay for the first analyte while performing a bidirectional assay
for the second analyte, because the flow from the second applicator through the chromatographic
medium is in the direction opposite to the flow of the sample from the sample preparation
zone.
[0073] The chromatographic medium, as described above, can be divided into two or more sectors
of different porosities to accommodate the particular analytes being assayed. In particular,
the first sector can include the specific binding partner for the first analyte, and
have a porosity suitable for the detection of the first analyte as an antigen. The
second sector can include the specific binding partner for the second analyte and
can have a porosity suitable for the detection of the second analyte as an antibody
in a serological sample.
[0074] This device is depicted in Figures 2A and 2B. Figure 2A depicts the device in the
open position, while Figure 2B is a sectional rear view of the device showing the
components in opposition. The device 100 has first and second opposable components
112 and 114 joined by a hinge 116. The first and second opposable components 112 and
114 have engagers such as locks 118 and 120, to hold the opposable components together.
The first and second opposable components 112 and 114 also have a ridge or gasket
122 surrounding them to prevent leakage.
[0075] The first opposable component 112 includes a chromatographic medium 124 with first
and second ends 126 and 128 and first and second surfaces 130 and 132. The chromatographic
medium 124 has therein in discrete, separated, non-overlapping zones, a specific binding
partner for the first analyte 134 and a specific binding partner for the second analyte
136. The chromatographic medium 124 also preferably includes a control zone 138 to
bind the detection reagent for the second analyte. Marked on or immediately adjacent
to the chromatographic medium 124 is a limit line 140.
[0076] The first opposable component 112 also has a first conductor 142 in operable contact
with the first end 126 of the chromatographic medium 124 and a second conductor 144
in operable contact with the second end 128 of the chromatographic medium 124.
[0077] The first opposable component 112 also includes a sample preparation zone 146 with
a first end 147 and a second end 149. The first end 147 of the sample preparation
zone 146 is in operable contact with a portion 133 of the chromatographic medium 124
between the specific binding partner for the first analyte 134 and the specific binding
partner for the second analyte 136. The portion 133 lies closer to the specific binding
partner for the second analyte 136. The sample preparation zone 146 is placed adjacent
to the first surface 130 of the chromatographic medium 124 but is preferably insulated
therefrom so that fluid flow does not occur from the sample preparation zone 146 to
the first surface 130 of the chromatographic medium 124. Also, fluid flow preferably
does not occur from the second end 149 of the sample preparation zone 146 to the chromatographic
medium 124 until the first and second opposable components 112 and 114 are brought
into opposition, with a gap 151 existing between the second end 149 of the sample
preparation zone 146 and the chromatographic medium 124. The sample preparation zone
146 preferably contains a resolubilizable dye to indicate the progress of the sample
through the chromatographic medium 124. The sample preparation zone 146 can also contain
one or more reagents for treatment of the sample.
[0078] The second opposable component 112 includes an absorber 148, a first applicator 150
separated from the absorber 148 and containing a specific binding partner for the
first analyte labeled with a detectable label in resolubilizable form, and a second
applicator 152 separated from the absorber 148 and containing a detection reagent
for the second analyte in resolubilizable form. The second opposable component 112
further preferably includes a first aperture 154 and a second aperture 156 for viewing
of the specific binding partner for the first analyte 134 and the specific binding
partner for the second analyte 136, respectively, when the first and second opposable
components 112 and 114 are brought into opposition to close the device 100.
[0079] When the first and second opposable components 112 and 114 are brought into opposition,
the absorber 148 comes into operable contact with the sample preparation zone 146,
including its second end 149, and with a portion 157 of the chromatographic medium
124 located closest to the second end 149 of the sample preparation zone 146 to withdraw
fluid from the sample preparation zone 146 and the chromatographic medium 124. The
first applicator 150 comes into operable contact with the first conductor 142, and
the second applicator 152 comes into operable contact with the second conductor 144.
[0080] In use, a first aqueous liquid is applied to the second applicator 152, and a first
aliquot of the sample to be assayed is applied to the first applicator 150. A second
aliquot of the sample is applied to the sample preparation zone 146. The second aliquot
of the sample applied to the sample preparation zone 146 is allowed to migrate from
the first end 147 of the sample preparation zone 146 through at least the portion
133 of the chromatographic medium 124 and through the specific binding partner for
the second analyte 136. The first and second opposable components 112 and 114 are
then brought into opposition to cause the absorber 148 to come into contact with the
sample preparation zone 146, including its second end 149, and with the portion 157
of the chromatographic medium 124. This also causes the first applicator 150 to come
into contact with the first conductor 142, and the second applicator 152 to come into
contact with the second conductor 144. The resolubilized labeled specific binding
partner for the first analyte as well as the first aliquot of the sample, originally
applied to the first applicator 150, are then allowed to migrate through at least
the region of the chromatographic medium containing the immobilized specific binding
partner to the first analyte 134. If the first analyte is present in the sample, a
ternary complex including the first analyte, the immobilized specific binding partner
to the first analyte, and the resolubilized labeled specific binding partner for the
first analyte is formed at zone 134. This complex is a typical sandwich complex.
[0081] The resolubilized detection reagent for the second analyte is then allowed to migrate
through at least a portion of the chromatographic medium 136 containing the immobilized
specific binding partner to the second analyte. This flow is driven by the absorber
148 withdrawing fluid from the sample preparation zone 146 in order to reverse flow
for the bidirectional serological assay performed for the second analyte. If the second
analyte is present in the sample, a ternary complex involving the immobilized specific
binding partner to the second analyte, the second analyte, and the detection reagent
is formed at zone 136. The first analyte and the second analyte are then detected
by observing and/or measuring the labeled specific binding partner to the first analyte
bound at zone 134 and the detection reagent for the second analyte bound at zone 136.
[0082] Typically, the first and second opposable components 112 and 114 are closed when
the sample migrating from the sample preparation zone 146 reaches the limit line 140.
This point is determined by observing the migration of the visible dye in the sample
preparation zone 146 after it is resolubilized by the sample.
[0083] Typically, the migration proceeds for about 30 seconds to 2 minutes before the first
and opposable components 112 and 114 are closed. The results are read after an additional
development time that varies with the sample, the dimensions of the chromatographic
medium, and the nature of the analytes and the specific binding partners, but which
is typically from about 30 second to about 2 minutes.
2. Device with Sample Preparation Zone Interrupting Chromatographic Medium
[0084] The device described above can be varied by having the sample preparation zone interrupt
the chromatographic medium instead of being placed in insulated contact with its first
surface, so that there are two separated chromatographic media. In this device, flow
is outward from the sample preparation zone to cnly the second chromatographic medium
when the first and second opposable components are not in opposition. The sample preparation
zone and the first chromatographic medium are bridged by the absorber when the first
and second opposable components are in contact.
[0085] The second component of this version of the device is basically similar to that of
the device described above.
[0086] The device comprises:
(1) a first opposable component including:
(a) a first chromatographic medium having a first end and a second end, the chromatographic
medium having thereon in a discrete zone a specific binding partner for a first analyte;
(b) a second chromatographic medium having a first end and a second end, the second
chromatographic medium having thereon in a discrete zone a specific binding partner
for a second analyte;
(c) a first conductor in operable contact with the first end of the first chromatographic
medium;
(d) a second conductor in operable contact with the second end of the second chromatographic
medium; and
(e) a sample preparation zone in operable contact with the first end of the second
chromatographic medium;
(2) a second opposable component including:
(a) an absorber;
(b) a first applicator separated from the absorber and containing a specific binding
partner to the first analyte labeled with a detectable label in a form that can be
resolubilized by the addition of an aqueous liquid to the first applicator; and
(c) a second applicator separated from the absorber and containing a detection reagent
for the second analyte in resolubilizable form.
[0087] The first and second opposable components are configured so that bringing the first
and second opposable components into opposition: (1) causes the absorber to come into
contact with the sample preparation zone and with the first chromatographic medium;
(2) causes the first applicator to come into operable contact with the first conductor;
and (3) causes the second applicator to come into contact with the second conductor.
This causes the absorber to draw fluid from the first and second applicators through
the first and second chromatographic media to the absorber, so that a unidirectional
assay is performed for the first analyte and a bidirectional assay is performed for
the second analyte.
[0088] This device is depicted in Figures 3A and 3B. Figure 3A shows the device in the open
position, while Figure 3B is a sectional rear view of the device with the components
in opposition. The device 200 has first and second opposable components 212 and 214
joined by a hinge 216, with engagers 218 and 220. The first and second opposable components
212 and 214 have a ridge or gasket 222 surrounding them to prevent leakage of samples
or reagents. The first opposable component 212 includes first and second chromatographic
media 224 and 226. The first chromatographic medium 224 has first and second ends
228 and 230 and first and second surfaces 232 and 234. The second chromatographic
medium 226 has first and second ends 236 and 238 and first and second surfaces 240
and 242. The first chromatographic medium 224 has in a discrete zone a specific binding
partner for the first analyte 244. The second chromatographic medium 226 has in a
similar discrete zone a specific binding partner for the second analyte 246, and preferably,
a control zone 248 that binds the detection reagent for the second analyte. Marked
on or immediately adjacent to the second chromatographic medium 226 is a limit line
250. The first opposable component 212 also has a first conductor 252 in operable
contact with the first end 228 of the first chromatographic medium 224, and a second
conductor 254 in operable contact with the second end 238 of the second chromatographic
medium 226. The first opposable component 212 also has a sample preparation zone 256
with first and second ends 257 and 259. The first end 257 of the sample preparation
zone 256 is in operable contact with the first end 236 of the second chromatographic
medium 226. The second end 259 of the sample preparation zone 256 is not in operable
contact with the second end 230 of the first chromatographic medium 224 until the
first and second opposable components 212 and 214 are brought into opposition, with
a gap 261 existing as described above. Typically, the sample preparation zone 256
is centrally located within the first opposable component 212. However, this is not
necessary, and in some applications, an asymmetrical location of the sample preparation
zone 256 may be desirable, depending on the dimensions of the chromatographic media.
The sample preparation zone 256 typically contains a visible dye that can be resolubilized
by the application of a sample to the sample preparation zone 256. This dye enables
the user to monitor the progress of the migration of the sample through the second
chromatographic medium 226.
[0089] The second opposable component 214 includes an absorber 258, a first applicator 260
separated from the absorber 258 and containing a specific binding partner for the
first analyte labeled with a detectable label in resolubilizable form, and a second
applicator 262, separated from the absorber 258 and containing a detection reagent
for the second analyte in resolubilizable form. The second opposable component 214
also includes a first aperture 264 to allow viewing of the zone of the specific binding
partner to the first analyte 244 and a second aperture 266 to allow viewing of the
zone of the immobilized specific binding partner for the second analyte 246 and, if
present, the control zone 248.
[0090] When the first and second opposable components 212 and 214 are brought into opposition,
the absorber 258 is brought into contact with the sample preparation zone 256 and
with the second end 230 of the first chromatographic medium 224. The first applicator
260 is brought into contact with the first conductor 252. The second applicator 262
is brought into contact with the second conductor 254.
[0091] An assay using this embodiment is performed in essentially the same manner as that
of the embodiment incorporating a single chromatographic medium with a sample preparation
zone in operable contact with its first surface. Briefly, a first aqueous liquid is
applied to the second applicator 262, a first aliquot of the sample is applied to
the first applicator 260, and a second aliquot of the sample is applied to the sample
preparation zone 256. The sample is allowed to migrate through at least a portion
of the second chromatographic medium including the discrete zone of the specific binding
partner to the second analyte 246 and the control zone 248, if present. When the sample
reaches the limit line 250, the first and second opposable components 212 and 214
are brought into opposition, applying the labeled specific binding partner to the
first analyte as well as the first aliquot of the sample in the first applicator 260
and the detection reagent for the second analyte in the second applicator 262 to the
first and second conductors 252 and 254. The first aliquot of the sample and the labeled
specific binding partner for the first analyte and the detection reagent for the second
analyte are then allowed to migrate through the first and second chromatographic media
224 and 226 and the analytes are detected as described above. This results in a unidirectional
assay being performed for the first analyte and a bidirectional assay being performed
for the second analyte.
III. ANALYTES, SPECIFIC BINDING PARTNERS, AND LABELS
A. Analytes
[0092] The analytes suitable for detection with an assay device according to the present
invention include antigens, haptens and antibodies. Antigens detectable with the device
include hemoglobin,
Streptococcus A and B antigens, antigens specific to the protozoan parasite
Giardia and viral antigens, including antigens specific for viruses such as feline leukemia
virus (FeLV) and the Australia antigen specific for hepatitis. In general, any protein,
carbohydrate, glycoprotein, or mucoprotein that is sufficiently large to be immunogenic
can be assayed as an antigen. Preparation of antibodies to such antigens is well understood
in the art and is described, example in B. Harlow and D. Lane, "Antibodies: A Laboratory
Manual" (Cold Spring Harbor Laboratory, Cold Spring Harbor, New York, 1988), pp. 53-137.
A particularly useful antigen with assay devices according to the present invention
is FeLV antigen.
[0093] In general, haptens are assayable by procedures using assay devices according to
the present invention when the hapten is sufficiently large to accommodate more than
one epitope. It is recognized that not all haptens are large enough to accommodate
more than one epitope; however, some haptens, though not large enough to induce antigen
formation when injected by themselves, are nevertheless large enough that they possess
more than one epitope. Such haptens of sufficient size are assayable with assay devices
according to the present invention.
[0094] Antibodies that can be assayed include virtually all antibodies produced in mammals,
including IgG, IgM, and other classes of antibodies. One antibody for which assay
devices according to the present invention are particularly useful is antibody to
feline immunodeficiency virus (FIV).
B. Specific Binding Partners
[0095] Specific binding partners for the analyte can include antibodies and specific binding
proteins. Antibodies can include IgG, IgM, and other classes of antibodies. The antibodies
can be polyclonal or monoclonal. For some applications, particularly those where a
certain degree of genetic variability may exist in the analyte being screened, due
to the existence of polymorphisms, polyclonal antibodies may prove most useful, because
they are typically raised against a number of determinants. In situations in which
a great degree of discrimination is sought between the analyte to be assayed and potentially
similar and interfering analytes, and genetic variability is not a problem, monoclonal
antibodies may be preferred. The use of bivalent or univalent antibody fragments,
including Fab, F(ab') and F(ab')
2 fragments, may be desirable in some applications. Because there is no need to form
a lattice of multiple interactions, the use of such fragments can reduce the background
while not significantly lowering sensitivity. Also within the scope of the invention
is the use of chemically modified intact antibody molecules and antibody fragments,
including hybrid antibodies assembled by
in vitro reassociation of subunits.
[0096] When the analyte is an antigen, the first and second specific binding partners are
typically identical, but need not be. The first specific binding partner is immobilized
to the chromatographic medium at the detection zone. Typically, the antibody is bound
to the detection zone covalently. Methods for covalently binding antibodies to solid
phases are well known in the art and are described, for example, in P. Tijssen, "Practice
and Theory of Enzyme Immunoassays," (Elsevier, Amsterdam, 1985), pp. 297-328. Noncovalent
attachment of the antibody to the solid phase can also be used in some cases, particularly
where the chromatographic medium is nitrocellulose or plastic.
[0097] Specific binding partners also include specific binding proteins, such as receptors
for protein hormones. These can substitute for antibodies in the assay. They can be
coupled to the chromatographic medium either covalently or noncovalently in much the
same way as antibodies.
[0098] When one of the analytes to be assayed is an antibody, the first specific binding
partner immobilized on the chromatographic medium is typically an antigen or an antigen
analogue for which the antibody to be assayed has specific binding affinity. In some
cases, the antigen analogue bound to the chromatographic medium can be extended by
a spacer to limit the steric hindrance resulting from the attachment of the antigen
or antigen analogue to the solid support, thereby improving binding affinity and efficiency.
The spacer typically contains groups such as saturated hydrocarbon, amide, or ester
linkages, although other stable spacer-forming groups are possible. Where the analyte
is an antibody and the corresponding antigen is a protein, methods of attachment to
the solid support similar to those above can be used. Such methods also are available
for antigens or antigen analytes other than proteins. For example, cellulose can be
activated with 1-(3-nitrobenzyloxymethyl) pyridinium chloride, to produce successively
nitrobenzyloxymethyl, aminobenzyloxymethyl, and diazobenzyloxymethyl groups. The latter
can react with several groups found in proteins, nucleic acids, and other molecules,
including phenol groups and aromatic amines.
[0099] When one of the analytes to be assayed is an antibody, the detection reagent is typically
a second antibody that binds the first antibody on the basis of a specificity other
than the specificity by which the first antibody (i.e. the analyte) binds its corresponding
antigen or hapten. For example, if the analyte is feline antibody to feline immunodeficiency
virus (FIV), the first specific binding partner bound by the solid support is typically
a protein from FIV that is the immunogen or the intact virus, and the detection reagent
is typically anti-cat IgG antibody produced in another species by immunization of
that species with cat IgG immunoglobulin.
[0100] The detection reagent can also be an antibody that is prepared on the basis of specificity
other than species specificity, such as subclass specificity.
C. Labels
[0101] The second specific binding partner for the first analyte and the detection reagent
for the second analyte are each labeled with a detectable label. A number of detectable
labels can be used. Preferably, the detectable label is a visually detectable label,
which permits detection and/or determination of the analytes by visual observation.
A preferred visually detectable label is a colloidal metal label. Preferably the colloidal
metal label is gold, silver, bronze, or tin; most preferably it is gold. The preparation
of gold-labeled antibodies is described in J. DeMey, "The Preparation and Use of Gold
Probes," in
Immunocytochemistry: Modern Methods and Applications (J. M. Polak & S. VanNoorden, eds., Wright, Bristol, England, 1986), ch. 8, pp. 115-145.
Antibodies labeled with colloidal gold are commercially available, such as from Sigma
Chemical Company, St. Louis, Missouri.
[0102] Alternatively, other colloidal labels, such as a colloidal sulfur label or a dye-silica
label, can also be used. In a less preferred alternative, the visually detectable
label can be a colored latex label. It is also possible to use other labels, such
as radioactive labels, fluorescent labels, or enzyme labels.
[0103] The invention is illustrated by the following Example. The Example is for illustrative
purposes only and is not to be construed as limiting the scope of the invention in
any manner.
EXAMPLE
Interrupted-Flow Assay Device for Detection of Rubella and Human Chorionic Gonadotropin
[0104] An interrupted-flow assay device according to the present invention was constructed
to detect both rubella and human chorionic gonadotropin (hCG) in a single test. The
assay for rubella is a serological assay for anti-rubella antibody, and the immunological
assay for hCG.
[0105] The device used for this assay is shown in Figures 4 and 5. Figure 4 shows the open
device 300. This device, when closed, is essentially similar to that shown in Figure
3B. The device 300 has a first opposable component 302 and a second opposable component
304. The first and second opposable components 302 and 304 are joined by a hinge 306.
The first and second opposable components 302 and 304 can be held in opposition by
a bevel closure 308.
[0106] The second opposable component 304 includes a first window 310 to allow observation
of the rubella test and a second window 312 to allow observation of the hCG test.
[0107] The second opposable component 304 has a first reagent pad 314 consisting of Lipore
(Grade 9254 glass fiber filter, Lydall Technical Papers, Rochester, New Hampshire)
glass fiber impregnated with a dried conjugate of anti-hCG-gold. For each pad, 10
µl of anti-hCG monoclonal antibody (Oy Medix Biochemica AB, Kauniainen, Finland) conjugated
to 40 nm colloidal gold (BioCell, Cardiff, Wales, United Kingdom) was mixed with 10
µl of conjugate diluent (5 mM borate, 0.1% Triton® X-100, 1% bovine serum albumin,
5% sucrose, pH 8.0) and was dried at 37°C for 30 minutes.
[0108] A second reagent pad 316 was constructed of Lipore glass fiber impregnated with dried
conjugates of goat anti-human IgG-gold and goat IgG-gold. For each pad, 8.125 µl goat
anti-human IgG (Jackson Laboratories, Bar Harbor, ME) conjugated to 15 nM colloidal
gold (EY Laboratories, San Mateo) was mixed with 2.0 µl goat IgG linked to 40 nm colloidal
gold (BioCell) and 37.5 µl of conjugate diluent as above, and dried at 37°C for 30
minutes.
[0109] The second opposable component 304 further includes an absorber 318 (Ahlstrom 270,
Ahlstrom Filtration, Holly Springs, Pennsylvania).
[0110] The first opposable component 302 includes a specimen pad 320 of Ahlstrom Cytosep.
[0111] The first opposable component 302 further includes a first chromatographic medium
322 of 5 µm nitrocellulose from Schleicher & Schuell (Keene, New Hampshire).
[0112] The first chromatographic medium 322 contains thereon a detection zone 324 of anti-hCG
antibody (Binax, Portland, Maine, polyclonal anti-whole hCG, 2 mg/ml). At the end
of the first chromatographic medium 302 furthest from the specimen pad 320 is a first
conductor 326 (Ahlstrom 1281).
[0113] The first opposable component 302 further includes a second chromatographic medium
328 comprising 12 µm nitrocellulose (Schleicher & Schuell). The second chromatographic
medium 328 has thereon a control zone 330 (anti-goat IgG (O.E.M. Concepts, Toms River,
New Jersey, 1 mg/ml).
[0114] The second chromatographic medium 328 on the first opposable component 302 further
includes a detection zone 332 containing rubella viral antigen at 0.25 mg/ml.
[0115] The first opposable component 302 further includes a printed limit line 334 and a
second conductor (Ahlstrom 1281) 336. The limit line 334 is located between the detection
zone 332 and the second conductor 336. The first and second chromatographic medium
322 and 328 and the first and second conductors 326 and 336 are backed by a polycarbonate
test strip backing (Lexan) 338.
[0116] For operation of the test, one drop of reconstituting buffer (0.005 M phosphate buffered
saline, 0.4% Tween 20, 1.25 mM HEPES, 0.0025% Triton® X-100, 0.0015% EDTA, 0.025%
sodium azide, pH 7.5), was added to the rubella reagent pad 316. One drop of serum
from the test subject was then added to the reagent pad for the hCG 314 and the specimen
pad 320. The serum in the reagent pad for hCG 314 reconstituted the anti-hCG-gold
conjugate dried in the pad. The serum added to the specimen pad 320 was allowed to
migrate through the second chromatographic medium 328 where, if present in the serum,
anti-rubella antibody was captured by the rubella antigen immobilized at the detection
zone 332.
[0117] As the serum front reached the limit line 334, the device was closed. Simultaneously,
the absorber 318 made contact with the upper portion of the first chromatographic
medium 322 (for determining hCG) and the lower portion of the second chromatographic
medium 328 (for testing for anti-rubella antibody), as well as the specimen pad 320.
The rubella reagent pad 316 applied conjugate (anti-human IgG and goat IgG) to the
second conductor 336. These reagents migrated down the second chromatographic medium
328 as serum was withdrawn from the second chromatographic medium 328 by the absorber
318. Anti-rubella IgG antibody captured by rubella antigen in the detection zone 332
was labeled by the passing anti-IgG gold conjugate to give a visible line at the detection
zone 332. The control line developed in the control zone 330 as the goat-IgG-gold
conjugate passed the anti-goat IgG line in the control zone 330 uncaptured reagents
were absorbed by the absorber 318.
[0118] The hCG reagent pad 314, to which sample had been applied, applied the conjugate
and the sample to the first conductor 326, and thereby to the first chromatographic
medium 322. If hCG was present in the sample, it was already labeled by gold, and
as it migrated past the detection zone 324 containing anti-hCG antibody, it was captured
to form a visible line at the detection zone 324 for hCG. Uncaptured reagents were
absorbed by the absorber 318.
[0119] Using this device, serum have been tested to detect levels of hCG that are clinically
significant. Levels of hCG greater than 25 mIU/ml and levels of rubella antibody greater
than 1/8 HAI Titer were detectable using this device.
ADVANTAGES OF THE INVENTION
[0120] Chromatographic assay devices according to the present invention can perform simultaneous
detection and/or determination of two analytes in the same sample using just one test
in one device. The devices allow for the detection of both an antigen, by a sandwich
immunoassay, and an antibody, by a serological immunoassay, in one test. This can
provide for the diagnosis of two diseases or conditions at once, or, alternatively,
for the detection of both an antigen asscciated with a pathogen or infectious agent
and an antibody associated with an immune response to the pathogen or infectious agent.
[0121] Chromatographic assay devices according to the present invention also provide an
advantage in being constructed of opposable elements. The use of opposable elements
provides great versatility, as it permits the performance of reactions in a number
of different sequences. This is possible because the use of such opposable elements
allows the delivery of reagents to precisely defined regions of a test strip or other
reaction component. The use of opposable elements also provides optimum performance
with minimum consumption of reagents by ensuring that reagents are not wasted by being
sequestered in dead volumes of apparatus. Finally, the use of opposable components
provides optimum containment of possibly contaminated blood samples, each as those
containing HIV or hepatitis virus.
[0122] Additionally, chromatographic assay devices according to the present invention allow
the rapid and accurate detection of clinically important analytes. The construction
of the devices allows more even application of the samples to the chromatographic
medium, and reduces interference that might otherwise be introduced by particulates
or colored samples. The use of colloidal metal labels in a resolubilizable form provides
extremely rapid kinetics of labeling and improves the performance of the assay. Additionally,
the construction and arrangement of the housing of the device aids in the performance
of the assay by assuring the withdrawal of excess immunoglobulin-containing sample
that could otherwise create interference in the serological assay.
[0123] Test methods using devices according to the present invention have a wide dynamic
range and are substantially free from false negatives that may occur in other test
methods at high concentrations of analyte.
[0124] Although the present invention has been described with considerable detail, with
reference to certain preferred versions thereof, other versions and embodiments are
possible. These versions include other arrangements of two-component devices that
operate by the basic principles described herein and simultaneously perform two assays
for different analytes in one assay device by blocking or restricting the flow of
sample from one portion of the chromatographic medium. Therefore, the scope of the
invention is determined by the following claims.
1. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising at least one chromatographic medium having
(1) a first end comprising a conjugate zone impregnated with a labeled specific binding
partner to the first analyte, (2) an intermediate first zone comprising an immobilized
specific binding partner to the first analyte, and (3) a second end having a second
zone comprising an immobilized antigen which specifically binds to the second analyte;
(b) a second opposable component having an absorber which is brought into fluid communication
with an area of the at least one chromatographic medium between the first and second
zones thereof when the first and second opposable components are brought into physical
contact; and
(c) a labeled specific binding partner to the second analyte impregnated in either
the first or second opposable component in a zone in downstream fluid communication
with the second zone;
wherein the first and second opposable components are capable of being brought
into physical contact to provide a unidirectional chromatographic specific binding
assay for the first analyte and a bidirectional chromatographic specific binding assay
for the second analyte by physically contacting the absorber to the first opposable
component after migration of an applied aqueous sample from the first end to the second
end of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in a first and second zones, respectively.
2. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising at least one chromatographic medium having
(1) a first end, (2) an intermediate first zone comprising an immobilized specific
binding partner to the first analyte, and (3) a second end having a second zone comprising
an immobilized antigen which specifically binds to the second analyte; and
(b) a second opposable component having (1) a first applicator impregnated with a
labeled specific binding partner for the first analyte which is brought into fluid
communication with the first zone when the first and second opposable components are
brought into physical contact, (2) an absorber which is brought into fluid communication
with an area of the at least one chromatographic medium between the first and second
zones thereof when the first and second opposable components are brought into physical
contact, and (3) a second applicator impregnated with a labeled specific binding partner
for the second analyte which is brought into fluid communication with the second zone,
when the first and second opposable components are brought into physical contact;
wherein the first and second opposable components are capable of being brought
into physical contact to provide a unidirectional chromatographic specific binding
assay for the first analyte and a bidirectional chromatographic specific binding assay
for the second analyte by physically contacting the absorber to the first opposable
component after migration of an applied aqueous sample from the first end to the second
end of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in the first and second zones, respectively.
3. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising at least one chromatographic medium having
(1) a first end comprising a first applicator impregnated with a labeled specific
binding partner to the first analyte, (2) an intermediate first zone comprising an
immobilized specific binding partner to the first analyte, and (3) a second end having
a second zone comprising an immobilized antigen which specifically binds to the second
analyte; and
(b) a second opposable component having (1) an absorber which is brought into fluid
communication with an area of the at least one chromatographic medium between the
first and second zones thereof when the first and second opposable components are
brought into physical contact, and (2) a second applicator impregnated with a labeled
specific binding partner for the second analyte which is brought into fluid communication
with the second zone when the first and second opposable components are brought into
physical contact;
wherein the first and second opposable components are capable of being brought
into physical contact to provide a unidirectional chromatographic specific binding
assay for the first analyte and a bidirectional chromatographic specific binding assay
fcr the second analyte by physically contacting the absorber to the first opposable
component after migration of an aqueous sample applied by the first applicator to
the second end of the first opposable component in order to reverse fluid flow direction
between the first and second ends, and detecting the first and second analytes by
detecting formation of labeled ternary complexes in the first and second zones, respectively;
and wherein the absorber substantially excludes the labeled specific binding partner
to the second analyte from the first zone by blocking the labeled specific binding
partner to the second analyte from migrating into the first zone.
4. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising:
(i) at least one chromatographic medium having (1) a first end, (2) an intermediate
first zone comprising an immobilized specific binding partner to the first analyte,
and (3) a second end having a second zone comprising an immobilized antigen which
specifically binds to the second analyte; and
(ii) a sample preparation zone located between the first zone and second zone; and
(b) a second opposable component having (1) a first applicator impregnated with a
labeled specific binding partner for the first analyte which is brought into fluid
communication with the first zone when the first and second opposable components are
brought into physical contact, (2) an absorber which is brought into fluid communication
with an area of the at least one chromatographic medium between the first and second
zones thereof when the first and second opposable components are brought into physical
contact, and (3) a second applicator impregnated with a labeled specific binding partner
for the second analyte which is brought into fluid communication with the second zone,
when the first and second opposable components are brought into physical contact;
wherein the first and second opposable components are capable of being brought
into physical contact to provide a unidirectional chromatographic specific binding
assay for the first analyte and a bidirectional chromatographic specific binding assay
for the second analyte by physically contacting the absorber to the first opposable
component after migration of an applied aqueous sample from the first end to the second
end of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in the first and second zones, respectively;
and wherein physical contacting of the absorber divides the first zone from the second
zone so that the labeled specific binding partner to the second analyte is substantially
excluded from the first zone by blocking the labeled specific binding partner to the
second analyte from flowing into the first zone.
5. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising at least one chromatographic medium having
in order of fluid communication (1) a first end, (2) a first applicator, (3) a conjugate
zone impregnated with a labeled specific binding partner to the first analyte bridging
the first end and the first applicator, (4) a first zone comprising an immobilized
specific binding partner to the first analyte, (5) a second zone comprising an immobilized
antigen which specifically binds to the second analyte, (6) a fluid conductor, and
(7) a second end; and
(b) a second opposable component comprising:
(i) an absorber which is brought into fluid communication with an area of the at least
one chromatographic medium between the first and second zones thereof when the first
and second opposable components are brought into physical contact; and
(ii) a second applicator impregnated with a labeled specific binding partner for the
second analyte which is brought into fluid communication with the fluid conductor,
when the first and second opposable components are brought into physical contact;
wherein the first and second opposable components are capable of being brought into
physical contact to provide a unidirectional chromatographic specific binding assay
for the first analyte and a bidirectional chromatographic specific binding assay for
the second analyte by physically contacting the absorber to the first opposable component
after migration of an applied aqueous sample from the first end to the second end
of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in the first and second zones, respectively.
6. The assay device of claim 5 wherein the second analyte is an antibody produced by
a mammalian species in response to an antigen, wherein the antigen is the same as
the immobilized antigen, and the labeled specific binding partner is a labeled antibody
that specifically binds to the second analyte by binding to the constant region of
the second analyte.
7. The assay device of claim 6 wherein the labeled antibody binds the second analyte
by binding to a species-specific determinant.
8. The assay device of claim 5 wherein the first and second zones of the at least one
chromatographic medium are of differing porosities.
9. The assay device of claim 8 wherein the at least one chromatographic medium is nitrocellulose.
10. A method for determining the presence or amount of at least two analytes in an aqueous
sample, comprising the sequential steps of:
(a) applying a first aliquot of the sample to the first applicator of the assay device
of claim 5;
(b) allowing the sample to migrate from the first applicator through the conjugate
zone and then through at least the fluid conductor of the at least one chromatographic
medium so that a first ternary complex is formed in the first zone if the first analyte
is present in the sample, the first ternary complex comprising the first analyte,
the labeled specific binding partner to the first analyte, and the Immobilized specific
binding partner to the first analyte;
(c) bringing the first and second opposable components into physical contact to cause
the second applicator to come into fluid communication with the at least one chromatographic
medium to draw fluid from the second applicator through the fluid conductor and through
the second zone of the at least one chromatographic medium from the fluid conductor
to the absorber so that a second ternary complex is formed in the second zone if the
second analyte is present in the sample, the second ternary complex comprising the
second analyte, the labeled specific binding partner to the second analyte, and the
immobilized antigen to the second analyte; and
(d) determining the presence or amount of the at least two analytes in the aqueous
sample by observing and/or measuring any detectable signal produced by the labeled
specific binding partner to the first analyte bound in the first ternary complex in
the first zone and any detectable signal produced by the labeled specific binding
partner to the second analyte bound in the second ternary complex in the second zone.
11. The method of claim 10 wherein the labeled specific binding partner to the first analyte
and the labeled specific binding partner to the second analyte each is labeled with
a detectable label and the step of observing and/or measuring the detectable signals
is performed visually.
12. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising at least one chromatographic medium having
in order of fluid communication (1) a first end, (2) a first fluid conductor, (3)
a sample preparation zone, (4) a first zone comprising an immobilized specific binding
partner to the first analyte, (5) a second zone comprising an immobilized antigen
which specifically binds to the second analyte, (6) a second fluid conductor, and
(7) a second end; and
(b) a second opposable component comprising:
(i) a first applicator impregnated with a resolubilizable labeled specific binding
partner for the first analyte which is brought into fluid communication with the first
fluid conductor when the first and second opposable components are brought into physical
contact;
(ii) an absorber which is brought into fluid communication with the sample preparation
zone of the at least one chromatographic medium when the first and second opposable
components are brought into physical contact; and
(iii) a second applicator impregnated with a resolubilizable labeled specific binding
partner for the second analyte which is brought into fluid communication with the
second fluid conductor when the first and second opposable components are brought
into physical contact;
wherein the first and second opposable components are capable of being brought into
physical contact to provide a unidirectional chromatographic specific binding assay
for the first analyte and a bidirectional chromatographic specific binding assay for
the second analyte by physically contacting the absorber to the first opposable component
after migration of an applied aqueous sample from the first end to the second end
of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in the first and second zones, respectively.
13. The assay device of claim 12 wherein the seccnd analyte is an antibody produced by
a mammalian species in response to an antigen, wherein the antigen is the same as
the immobilized antigen, and the labeled specific binding partner is a labeled antibody
that specifically binds to the second analyte by binding to the constant region of
the second analyte.
14. The assay device of claim 13 wherein the labeled antibody binds the second analyte
by binding to a species-specific determinant.
15. The assay device of claim 12 wherein the first and second zones of the at least one
chromatographic medium are of different porosities.
16. The assay device of claim 15 wherein the at least one chromatographic medium is nitrocellulose.
17. A method for determining the presence or amount of at least two analytes in an aqueous
sample, comprising the sequential steps of:
(a) applying a first aqueous liquid to the second applicator of the assay device of
claim 12 to resolubilize the labeled specific binding partner to the second analyte;
(b) applying a first aliquot of the sample to the first applicator to resolubilize
the labeled specific binding partner to the first analyte;
(c) applying a second aliquot of the sample to the sample preparation zone;
(d) allowing the second aliquot of the sample applied to the sample preparation zone
to migrate through at least the second fluid conductor of the at least one chromatographic
medium;
(e) bringing the first and second opposable components into physical contact to cause
the absorber to come into contact with the at least one chromatographic medium, the
first applicator to come into contact with the first fluid conductor, and the second
applicator to come into contact with the second fluid conductor;
(f) allowing the first aliquot of the sample and the resolubilized labeled specific
binding partner to the first analyte to migrate through at least the first zone of
the at least one chromatographic medium so that a first ternary complex is formed
in the first zone if the first analyte is present in the sample, the first ternary
complex comprising the first analyte, the labeled specific binding partner to the
first analyte, and the immobilized specific binding partner to the first analyte;
and allowing the resolubilized labeled specific binding partner to the second analyte
to migrate through at least the second zone of the at least one chromatographic medium
so that a second ternary complex is formed in the second zone if the second analyte
is present in the sample, the second ternary complex comprising the second analyte,
the labeled specific binding partner to the second analyte, and the immobilized antigen
to the second analyte; and
(g) determining the presence or amount of the first analyte and the second analyte
in the aqueous sample by observing and/or measuring any detectable signal produced
by the labeled specific binding partner to the first analyte bound in the first ternary
complex in the first zone and any detectable signal produced by the labeled specific
binding partner to the second analyte bound in the second ternary complex in the second
zone.
18. The method of claim 17 wherein the labeled specific binding partner for the first
analyte and the labeled specific binding partner to the second analyte are each labeled
with a visually detectable label and the step of observing and/or measuring the detectable
signals is performed visually.
19. An assay device for detecting at least two analytes in an aqueous sample, a first
analyte that is an antigen and a second analyte that is an antibody, the assay device
comprising:
(a) a first opposable component comprising:
(i) a first chromatographic medium having in order of fluid communication (1) a first
end, (2) a first fluid conductor, (3) a first zone comprising an immobilized specific
binding partner to the first analyte, and (4) a second end; and
(ii) a second chromatographic medium having in order of fluid communication (1) a
first end, (2) a sample preparation zone, (3) a second zone comprising an immobilized
antigen which specifically binds to the second analyte, (4) a second fluid conductor,
and (5) a second end;
(b) a second opposable component comprising:
(i) a first applicator impregnated with a resolubilizable labeled specific binding
partner for the first analyte which is brought into fluid communication with the first
fluid conductor when the first and second opposable components are brought into physical
contact;
(ii) an absorber which is brought into fluid communication with the sample preparation
zone and with the first chromatographic medium when the first and second opposable
components are brought into physical contact; and
(iii) a second applicator impregnated with a resolubilizable labeled specific binding
partner for the second analyte which is brought into fluid communication with the
second fluid conductor, when the first and second opposable components are brought
into physical contact;
wherein the first and second opposable components are capable of being brought
into physical contact to provide a unidirectional chromatographic specific binding
assay for the first analyte and a bidirectional chromatographic specific binding assay
for the second analyte by physically contacting the absorber to the first opposable
component after migration of an applied aqueous sample from the first end to the second
end of the first opposable component in order to reverse fluid flow direction between
the first and second ends, and detecting the first and second analytes by detecting
formation of labeled ternary complexes in the first and second zones, respectively.
20. The assay device of claim 19 wherein the second analyte is an antibody produced by
a mammalian species in response to an antigen, wherein the antigen is the same as
the immobilized antigen, and the labeled specific binding partner is a labeled antibody
that specifically binds to the second analyte by binding to the constant region of
the second analyte.
21. The assay device of claim 20 wherein the labeled antibody binds to the second analyte
by binding to a species-specific determinant.
22. The assay device of claim 19 wherein the first and second chromatographic media are
of differing porosities.
23. The assay device of claim 22 wherein the first and second chromatographic media are
each nitrocellulose.
24. A method for determining the presence or amount of at least two analytes simultaneously
in an aqueous sample, comprising the sequential steps of:
(a) applying a first aqueous liquid to the second applicator of the assay device of
claim 19 to resolubilize the labeled specific binding partner to the second analyte;
(b) applying a first aliquot of the sample to the first applicator of the assay device
to resolubilize the labeled specific binding partner to the first analyte;
(c) applying a second aliquot of the sample to the sample preparation zone;
(d) allowing the second aliquot of the sample applied to the sample preparation zone
to migrate through at least the second fluid conductor of the second chromatographic
medium;
(e) bringing the first and second opposable components into physical contact tc cause
the absorber to come into contact with the sample preparation zone and the first chromatographic
medium, to cause the first applicator to come into contact with the first fluid conductor,
and to cause the second applicator to come into contact with the second fluid conductor;
(f) allowing the first aliquot of the sample and the resolubilized labeled specific
binding partner to the first analyte to migrate through at least the first zone of
the chromatographic medium and allowing the resolubilized labeled specific binding
partner to the second analyte to migrate through at least the second zone of the second
chromatographic medium so that a first ternary complex is formed in the first zone
of the first chromatographic medium if the first analyte is present in the sample,
the first ternary complex comprising the first analyte, the labeled specific binding
partner to the first analyte, and the immobilized specific binding partner to the
first analyte; and so that a second ternary complex is formed in the second zone of
the second chromatographic medium if the second analyte is present in the sample,
the second ternary complex comprising the second analyte, the labeled specific binding
partner to the second analyte, and the immobilized antigen to the second analyte;
and
(g) determining the presence or amount of the first analyte and the second analyte
in the aqueous sample by observing and/or measuring any detectable signal produced
by the labeled specific binding partner to the first analyte bound in the first ternary
complex in the first zone in the first chromatographic medium and any detectable signal
produced by the labeled specific binding partner to the second analyte bound in the
second ternary complex in the second zone of the chromatographic medium.
25. The method of claim 24 wherein the labeled specific binding partner for the first
analyte and the labeled specific binding partner to the second analyte are each labeled
with a visually detectable label and the step of observing and/or measuring the detectable
signals is performed visually.
1. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, mit wenigstens einem chromatographischen
Medium, das (1) ein erstes Ende, das eine mit einem markierten, zum ersten Analyten
spezifischen Bindungspartner imprägnierte konjugierte Zone umfaßt, (2) eine erste
Zwischenzone, die einen immobilisierten, zum ersten Analyten spezifischen Bindungspartner
umfaßt, und (3) ein zweites Ende aufweist, das eine zweite Zone aufweist, die ein
immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet;
(b) einen zweiten gegenüberstellbaren Bestandteil, der einen Absorber aufweist, der
mit einem Bereich des wenigstens einen chromatographischen Mediums in Strömungsmittelverbindung
zwischen dessen erster und zweiter Zone gebracht wird, wenn die ersten und zweiten
gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht werden; und
(c) ein markierter, zum zweiten Analyten spezifischer Bindungspartner, der in entweder
dem ersten oder zweiten gegenüberstellbaren Bestandteil in einer Zone in strömungsabwärts
gerichteter Strömungsmittelverbindung mit der zweiten Zone imprägniert ist;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten durch körperliches in Kontaktbringen des Absorbers mit dem
ersten gegenüberstellbaren Bestandteil nach Migration einer aufgebrachten wässrigen
Probe vom ersten Ende zum zweiten Ende des ersten gegenüberstellbaren Bestandteils
bereitzustellen, um die Strömungsmittel-Strömungsrichtung zwischen dem ersten und
zweiten Ende umzukehren, und durch Erfassung des ersten und zweiten Analyten durch
die Erfassung der Bildung von markierten Dreifachkomplexen in einer ersten bzw. zweiten
Zone.
2. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, mit wenigstens einem chromatographischen
Medium, das (1) ein erstes Ende, (2) eine erste Zwischenzone, die einen immobilisierten,
zum ersten Analyten spezifischen Bindungspartner umfaßt, und (3) ein zweites Ende
aufweist, das eine zweite Zone aufweist, die ein immobilisiertes Antigen umfaßt, das
spezifisch an den zweiten Analyten bindet; und
(b) einen zweiten gegenüberstellbaren Bestandteil, der (1) einen ersten Applikator,
der mit einem markierten, für den ersten Analyten spezifischen Bindungspartner imprägniert
ist, der in Strömungsmittelverbindung mit der ersten Zone gebracht wird, wenn die
ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht
werden, (2) einen Absorber, der in Strömungsmittelverbindung mit einem Bereich des
wenigstens einen chromatographischen Mediums zwischen dessen erster und zweiter Zone
gebracht wird, wenn die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt gebracht werden, und (3) einen zweiten Applikator aufweist, der mit einem
markierten, für den zweiten Analyten spezifischen Bindungspartner imprägniert ist,
der mit der zweiten Zone in Strömungsmittelverbindung gebracht wird, wenn die ersten
und zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten durch körperliches in Kontaktbringen des Absorbers mit dem
ersten gegenüberstellbaren Bestandteil nach Migration einer aufgebrachten wässrigen
Probe vom ersten Ende zum zweiten Ende des ersten gegenüberstellbaren Bestandteils
bereitzustellen, um die Strömungsmittel-Strömungsrichtung zwischen dem ersten und
zweiten Ende umzukehren, und durch Erfassung des ersten und zweiten Analyten durch
Erfassung der Bildung von markierten Dreifachkomplexen in der ersten bzw. zweiten
Zone.
3. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, der wenigstens ein chromatographisches
Medium umfaßt, das (1) ein erstes Ende, das einen ersten Applikator umfaßt, der mit
einem markierten zum ersten Analyten spezifischen Bindungspartner imprägniert ist,
(2) eine erste Zwischenzone, die einen immobilisierten, zum ersten Analyten spezifischen
Bindungspartner umfaßt, und (3) ein zweites Ende aufweist, das eine zweite Zone aufweist,
die ein immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet;
und
(b) einen zweiten gegenüberstellbarern Bestandteil, der (1) einen Absorber, der in
Strömungsmittelverbindung mit einem Bereich des wenigstens einen chromatographischen
Mediums zwischen dessen erster und zweiter Zone gebracht wird, wenn die ersten und
zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht werden,
und (2) einen zweiten Applikator aufweist, der mit einem markierten, für den zweiten
Analyten spezifischen Bindungspartner imprägniert ist, der in Strömungsmittelverbindung
mit der zweiten Zone gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromato-graphische spezifische Bindungsuntersuchung
für den zweiten Analyten durch körperliches in Kontaktbringen des Absorbers mit dem
ersten gegenüberstellbaren Bestandteil nach Migration einer wässrigen Probe die von
dem ersten Applikator auf das zweite Ende des ersten gegenüberstellbaren Bestandteils
aufgebracht wird, bereitzustellen, um die Strömungsmittel-Strömungsrichtung zwischen
dem ersten und zweiten Ende umzukehren, und durch Erfassung des ersten und zweiten
Analyten durch Erfassung der Bildung von markierten Dreifachkomplexen in der ersten
bzw. zweiten Zone; und wobei der Absorber den markierten, zum zweiten Analyten spezifischen
Bindungspartner im wesentlichen dadurch von der ersten Zone ausschließt, daß eine
Migration des markierten, zum zweiten Analyten spezifischen Bindungspartners in die
erste Zone blockiert wird.
4. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, der umfaßt:
(i) wenigstens ein chromatographisches Medium, das ein (1) erstes Ende, (2) eine erste
Zwischenzone, die einen immobilisierten, zum ersten Analyten spezifischen Bindungspartner
umfaßt, und (3) ein zweites Ende aufweist, das eine zweite Zone aufweist, die ein
immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet; und
(ii) eine Probenvorbereitungszone, die zwischen der ersten und der zweiten Zone angeordnet
ist; und
(b) einen zweiten gegenüberstellbaren Bestandteil, der (1) einen ersten Applikator,
der mit einem markierten, für den ersten Analyten spezifischen Bindungspartner imprägniert
ist, der mit der ersten Zone in Strömungsmittelverbindung gebracht wird, wenn die
ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht
werden, (2) einen Absorber, der in Strömungsmittelverbindung mit einem Bereich des
wenigstens einen chromatographischen Mediums zwischen dessen erster und zweiter Zone
gebracht wird, wenn die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt gebracht werden, und (3) einen zweiten Applikator aufweist, der mit einem
markierten, für den zweiten Analyten spezifischen Bindungspartner imprägniert ist,
der mit der zweiten Zone in Strömungsmittelverbindung gebracht wird, wenn die ersten
und zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten bereitzustellen, indem der Absorber zum ersten gegenüberstellbaren
Bestandteil nach Migration einer aufgebrachten wässrigen Probe vom ersten Ende zum
zweiten Ende des ersten gegenüberstellbaren Bestandteils in Kontakt gebracht wird,
um die Strömungsmittel-Strömungsrichtung zwischen dem ersten und zweiten Ende umzukehren,
und durch Erfassung des ersten und zweiten Analyten durch Erfassung der Bildung von
markierten Dreifachkomplexen in der ersten bzw. zweiten Zone; und wobei das körperliche
in Kontaktbringen des Absorbers die erste Zone von der zweiten Zone derartig teilt,
daß der markierte, zum zweiten Analyten spezifische Bindungspartner im wesentlichen
von der ersten Zone ausgeschlossen wird, indem der markierte, zum zweiten Analyten
spezifische Bindungspartner daran gehindert wird, in die erste Zone zu strömen.
5. Untersuchungsvorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist, und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungsvorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, der wenigstens ein chromatographisches
Medium umfaßt, das in der Reihenfolge der Strömungsmittelverbindung (1) ein erstes
Ende, (2) einen ersten Applikator, (3) eine konjugierte Zone, die mit einem markierten,
zum ersten Analyten spezifischen Bindungspartner imprägniert ist, die das erste Ende
und den ersten Applikator überbrückt, (4) eine erste Zone, die einen immobilisierten,
zum ersten Analyten spezifischen Bindungspartner umfaßt, (5) eine zweite Zone, die
ein immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet,
(6) einen Strömungsmittelleiter, und (7) ein zweites Ende aufweist; und
(b) einen zweiten gegenüberstellbaren Bestandteil, der umfaßt:
(i) einen Absorber, der in Strömungsmittelverbindung mit einem Bereich des wenigstens
einen chromatographischen Mediums zwischen dessen erster und zweiter Zone gebracht
wird, wenn die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt gebracht werden; und
(ii) einen zweiten Applikator, der mit einem markierten, für den zweiten Analyten
spezifischen Bindungspartner imprägniert ist, der in Strömungsmittelverbindung mit
dem Strömungsmittelleiter gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten bereitzustellen, indem der Absorber zum ersten gegenüberstellbaren
Bestandteil nach Migration einer aufgebrachten wässrigen Probe vom ersten zum zweiten
Ende des ersten gegenüberstellbaren Bestandteils körperlich in Kontakt gebracht wird,
um die Strömungsmittel-Strömumgsrichtung zwischen dem ersten und zweiten Ende umzukehren,
und durch Erfassung des ersten und zweiten Analyten durch Erfassung der Bildung von
markierten Dreifachkomplexen in der ersten bzw. zweiten Zone.
6. Untersuchungs-Vorrichtung nach Anspruch 5,
bei der der zweite Analyt ein durch eine Säugetierspezies in Antwort auf ein Antigen
hergestellter Antikörper ist, wobei das Antigen dasgleiche wie das immobilisierte
Antigen ist, und der markierte spezifische Bindungspartner ein markierter Antikörper
ist, der spezifisch an den zweiten Analyten bindet, indem er an die konstante Region
des zweiten Analyten bindet.
7. Untersuchungs-Vorrichtung nach Anspruch 6,
bei der der markierte Antikörper den zweiten Analyten bindet, indem er an die Spezies-spezifische
Determinante bindet.
8. Untersuchungs-Vorrichtung nach Anspruch 5,
bei der die ersten und zweiten Zonen des wenigstens einen chromatographischen Mediums
von unterschiedlicher Porosität sind.
9. Untersuchungs-Vorrichtung nach Anspruch 8,
bei der das wenigstens eine chromatographische Medium Nitrozellulose ist.
10. Verfahren zur Feststellung des Vorhandenseins oder der Menge von wenigstens zwei Analyten
in einer wässrigen Probe, das die aufeinanderfolgenden Schritte umfaßt:
(a) Aufbringung einer ersten Teilmenge der Probe auf den ersten Applikator der Untersuchungs-Vorrichtung
nach Anspruch 5;
(b) Migrierenlassen der Probe vom ersten Applikator durch die konjugierte Zone und
dann durch den wenigstens einen Strömungsmittelleiter des wenigstens einen chromatographischen
Mediums derart, daß ein erster Dreifachkomplex in der ersten Zone gebildet wird, wenn
der erste Analyt in der Probe vorhanden ist, wobei der erste Dreifachkomplex den ersten
Analyten, den markierten, zum ersten Analyten spezifischen Bindungspartner, und den
immobilisierten, zum ersten Analyten spezifischen Bindungspartner umfaßt;
(c) körperliches in Kontaktbringen der ersten und zweiten gegenüberstellbaren Bestandteile,
um zu bewirken, daß der zweite Applikator in Strömungsmittelverbindung mit dem wenigstens
einen chromatographischen Medium kommt, um Strömungsmittel vom zweiten Applikator
durch den Strömungsmittelleiter und durch die zweite Zone des wenigstens einen chromatographischen
Mediums vom Strömungsmittelleiter zum Absorber zu ziehen, derart, daß ein zweiter
Dreifachkomplex in der zweiten Zone gebildet wird, wenn der zweite Analyt in der Probe
vorhanden ist, wobei der zweite Dreifachkomplex den zweiten Analyten, den zum markierten,
zum zweiten Analyten spezifischen Bindungspartner, und das immobilisierte Antigen
zum zweiten Analyten umfaßt; und
(d) Feststellung des Vorhandenseins oder der Menge von der wenigstens zwei Analyten
in der wässrigen Probe durch Beobachtung und/oder Messung irgendeines erfaßbaren Signals,
das von dem markierten, zum zweiten Analyten spezifischen Bindungspartner erzeugt
wird, der im ersten Dreifachkomplex in der ersten Zone gebunden ist, und irgendeines
erfaßbaren Signals, das durch den markierten, zum zweiten Analyten spezifischen Bindungspartner
erzeugt wird, der im zweiten Dreifachkomplex in der zweiten Zone gebunden ist.
11. Verfahren nach Anspruch 10,
bei dem der markierte, zum ersten Analyten spezifische Bindungspartner, und der markierte,
zum zweiten Analyten spezifische Bindungspartner jeweils mit einer erfaßbaren Markierung
markiert ist, und der Schritt der Beobachtung und/oder Messung des erfaßbaren Signals
visuell durchgeführt wird.
12. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist, und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, mit wenigstens einem chromatographischen
Medium, das zur Strömungsmittelverbindung (1) ein erstes Ende, (2) einen ersten Strömungsmittelleiter,
(3) eine Probenvorbereitungszone, (4) eine erste Zone, die einen immobilisierten,
zum ersten Analyten spezifischen Bindungspartner umfaßt, (5) eine zweite Zone, die
ein immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet,
(6) einen zweiten Strömungsmittelleiter und (7) ein zweites Ende aufweist; und
(b) ein zweiter gegenüberstellbarer Bestandteil, der umfaßt:
(i) einen ersten Applikator, der mit einem wiederauflösbaren markierten, für den ersten
Analyten spezifischen Bindungspartner imprägniert ist, der mit dem ersten Strömungsmittelleiter
in Strömungsmittelverbindung gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden;
(ii) ein Absorber, der in Strömungsmittelverbindung mit der Probenvorbereitungszone
des wenigstens einen chromatographischen Mediums gebracht wird, wenn die ersten und
zweiten gegenüberstellbaren Bestandteile in körperlichen Kontakt gebracht werden;
und
(iii) ein zweiter Applikator, der mit einem wiederauflösbaren markierten, für den
zweiten Analyten spezifischen Bindungspartner imprägniert ist, der in Strömungsmittelverbindung
mit dem zweiten Strömungsmittelleiter gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und einen bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten durch körperliches in Kontaktbringen des Absorbers mit dem
ersten gegenüberstellbaren Bestandteil nach Migration einer aufgebrachten wässrigen
Probe vom ersten zum zweiten Ende des ersten gegenüberstellbaren Bestandteils bereitzustellen,
um die Strömungsmittel-Strömungsrichtung zwischen dem ersten und zweiten Ende umzukehren,
und durch Erfassung des ersten und zweiten Analyten durch Erfassung der Bildung von
markierten Dreifachkomplexen in der ersten bzw. zweiten Zone.
13. Untersuchungs-Vorrichtung nach Anspruch 12,
bei der der zweite Analyt ein Antikörper ist, der durch eine Säugetierspezies in Antwort
auf ein Antigen erzeugt wurde, wobei das Antigen dasgleiche wie das immobilisierte
Antigen ist, und der markierte spezifische Bindungspartner ein markierter Antikörper
ist, der spezifisch an den zweiten Analyten durch Bindung an die konstante Region
des zweiten Analyten bindet.
14. Untersuchungs-Vorrichtung nach Anspruch 13,
bei der der markierte Antikörper den zweiten Analyten durch Bindung an eine spezies-spezifische
Determinante bindet.
15. Untersuchungs-Vorrichtung nach Anspruch 12,
bei der die ersten und zweiten Zonen des wenigstens einen chromatographischen Mediums
von unterschiedlicher Porosität sind.
16. Untersuchungs-Vorrichtung nach Anspruch 15,
bei der das wenigstens eine chromatographische Medium Nitrozellulose ist.
17. Verfahren zur Feststellung des Vorhandenseins oder der Menge von wenigstens zwei Analyten
in einer wässrigen Probe, das die aufeinanderfolgenden Schritte umfaßt:
(a) Aufbringung einer ersten wässrigen Flüssigkeit auf den zweiten Applikator der
Untersuchungs-Vorrichtung nach Anspruch 12 zur Wiederauflösung des markierten, zum
zweiten Analyten spezifischen Bindungspartners;
(b) Aufbringung einer ersten Teilmenge der Probe auf den ersten Applikator zur Wiederauflösung
des markierten, zum ersten Analyten spezifischen Bindungspartners;
(c) Aufbringung einer zweiten Teilmenge der Probe auf die Probenvorbereitungszone;
(d) Migrierenlassen der zweiten Teilmenge der auf die Probenvorbereitungszone aufgebrachten
Probe durch wenigstens den zweiten Strömungsmittelleiter des wenigstens einen chromatographischen
Mediums;
(e) körperliches Inkontaktbringen des ersten und zweiten gegenüberstellbaren Bestandteils,
um zu bewirken, daß der Absorber mit dem wenigstens einen chromatographischen Medium
in Kontakt kommt, der erste Applikator mit dem ersten Strömungsmittelleiter in Kontakt
kommt, und der zweite Applikator mit dem zweiten Strömungsmittelleiter in Kontakt
kommt;
(f) Migrierenlassen der ersten Teilmenge der Probe und des wieder aufgelösten, markierten,
zum ersten Analyten spezifischen Bindungspartner durch wenigstens die erste Zone des
wenigstens einen chromatographischen Mediums, so daß ein erster Dreifachkomplex in
der ersten Zone gebildet wird, wenn der erste Analyt in der Probe vorhanden ist, wobei
der erste Dreifachkomplex den ersten Analyten, den zum ersten Analyten spezifischen
Bindungspartner, und den immobilisierten, zum ersten Analyten spezifischen Bindungspartner
umfaßt; und Migrierenlassen des wiederaufgelösten, markierten, zum zweiten Analyten
spezifischen Bindungspartners durch wenigstens die zweite Zone des wenigstens einen
chromatographischen Mediums, so daß ein zweiter Dreifachkomplex in der zweiten Zone
gebildet wird, wobei der zweite Dreifachkomplex den zweiten Analyten, den zum zweiten
Analyten markierten spezifischen Bindungspartner, und das immobilisierte Antigen zum
zweiten Analyten umfaßt; und
(g) Feststellung des Vorhandenseins oder der Menge des ersten Analyten und des zweiten
Analyten in der wässrigen Probe durch Beobachtung und/oder Messung irgendeines meßbaren
Signals, das durch den markierten, zum ersten Analyten spezifischen Bindungspartner,
der im ersten Dreifachkomplex in der ersten Zone gebunden ist, erzeugt wird, und irgendeines
erfaßbaren Signals, das durch den markierten, zum zweiten Analyten spezifischen Bindungspartner,
der im zweiten Dreifachkomplex in der zweiten Zone gebunden ist, erzeugt wird.
18. Verfahren nach Anspruch 17,
bei dem der markierte, für den ersten Analyten spezifische Bindungspartner und der
markierte, zum zweiten Analyten spezifische Bindungspartner jeweils mit einer visuell
erfaßbaren Markierung markiert sind und der Schritt der Beobachtung und/oder Messung
des erfaßbaren Signals visuell durchgeführt wird.
19. Untersuchungs-Vorrichtung zur Erfassung von wenigstens zwei Analyten in einer wässrigen
Probe, nämlich einen ersten Analyten, der ein Antigen ist, und einen zweiten Analyten,
der ein Antikörper ist, wobei die Untersuchungs-Vorrichtung umfaßt:
(a) einen ersten gegenüberstellbaren Bestandteil, der umfaßt:
(i) ein erstes chromatographisches Medium, das in der Reihenfolge der Strömungsmittelverbindung
(1) ein erstes Ende, (2) einen ersten Strömungsmittelleiter, (3) eine erste Zone,
die einen immobilisierten, zum ersten Analyten spezifischen Bindungspartner umfaßt,
und (4) ein zweites Ende aufweist; und
(ii) ein zweites chromatographisches Medium, das in der Reihenfolge der Strömungsmittelverbindung
(1) ein erstes Ende, (2) eine Probenvorbereitungszone, (3) eine zweite Zone, die ein
immobilisiertes Antigen umfaßt, das spezifisch an den zweiten Analyten bindet, (4)
einen zweiten Strömungsmittelleiter, und (5) ein zweites Ende aufweist;
(b) ein zweiter gegenüberstellbarer Bestandteil, der umfaßt:
(i) einen ersten Applikator, der mit einem wiederauflösbaren markierten, für den ersten
Analyten spezifischen Bindungspartner imprägniert ist, der mit dem ersten Strömungsmittelleiter
in Strömungsmittelverbindung gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden;
(ii) einen Absorber, der mit der Probenvorbereitungszone mit dem ersten chromatographischen
Medium in Strömungsmittelverbindung gebracht wird, wenn die ersten und zweiten gegenüberstellbaren
Bestandteile in körperlichen Kontakt gebracht werden; und
(iii) ein zweiter Applikator, der mit einem wiederauflösbaren markierten, für den
zweiten Analyten spezifischen Bindungspartner imprägniert ist, der mit dem zweiten
Strömungsmittelleiter in Strömungsmittelverbindung gebracht wird, wenn die ersten
und zweiten gegenüberstellbaren Bestandteil in körperlichen Kontakt gebracht werden;
wobei die ersten und zweiten gegenüberstellbaren Bestandteile in körperlichen
Kontakt bringbar sind, um eine unidirektionale chromatographische spezifische Bindungsuntersuchung
für den ersten Analyten und eine bidirektionale chromatographische spezifische Bindungsuntersuchung
für den zweiten Analyten durch körperliches Inkontaktbringen des Absorbers mit dem
ersten gegenüberstellbaren Bestandteil nach Migration einer aufgebrachten wässrigen
Probe vom ersten zum zweiten Ende des ersten gegenüberstellbaren Bestandteils bereitzustellen,
um die Strömungsmittelströmungsrichtung zwischen dem ersten und zweiten Ende umzukehren,
und durch Erfassung des ersten und zweiten Analyten durch Erfassung der Bildung von
markierten Dreifachkomplexen in der ersten und bzw. zweiten Zone.
20. Untersuchungs-Vorrichtung nach Anspruch 19,
bei der der zweite Analyt ein Antikörper ist, der durch eine Säugetierspezies in Antwort
auf ein Antigen erzeugt wird, wobei das Antigen dasgleiche wie das immobilisierte
Antigen ist, und der markierte, spezifische Bindungspartner ein markierter Antikörper
ist, der spezifisch an den zweiten Analyten durch Bindung an die konstante Region
des zweiten Analyten bindet.
21. Untersuchungs-Vorrichtung nach Anspruch 20,
bei der der markierte Antikörper an den zweiten Analyten durch Bindung an eine spezies-spezifische
Determinante bindet.
22. Untersuchungs-Vorrichtung nach Anspruch 19,
bei der das erste und zweite chromatographische Medium von unterschiedlicher Porosität
ist.
23. Untersuchungs-Vorrichtung nach Anspruch 22,
bei der das erste und zweite chromatographische Medium jeweils aus Nitrozellulose
besteht.
24. Verfahren zur Feststellung des Vorhandenseins oder der Menge von wenigstens zwei Analyten
gleichzeitig in einer wässrigen Probe, das die aufeinanderfolgenden Schritte umfaßt:
(a) Aufbringung einer ersten wässrigen Flüssigkeit auf den zweiten Applikator der
Untersuchungs-Vorrichtung nach Anspruch 19, um den markierten, zum zweiten Analyten
spezifischen Bindungspartner wieder aufzulösen;
(b) Aufbringung einer ersten Teilmenge der Probe auf den ersten Applikator der Untersuchungs-Vorrichtung,
um den markierten, zum ersten Analyten spezifischen Bindungspartner wieder aufzulösen;
(c) Aufbringung einer zweiten Teilmenge der Probe auf die Probenvorbereitungszone;
(d) Migrierenlassen der zweiten Teilmenge der auf die Probenvorbereitungszone aufgebrachten
Probe durch wenigstens den zweiten Strömungsmittelleiter des zweiten chromatographischen
Mediums;
(e) körperliches Inkontaktbringen der ersten und zweiten gegenüberstellbaren Bestandteile,
um zu bewirkenen, daß der Absorber mit der Probenvorbereitungszone und dem ersten
chromatographischen Medium in Kontakt kommt, um zu bewirken, daß der erste Applikator
mit dem ersten Strömungsmittelleiter in Kontakt kommt, und zu bewirken, daß der zweite
Applikator mit dem zweiten Strömungsmittelleiter in Kontakt kommt;
(f) Migrierenlassen der ersten Teilmenge der Probe und des wiederaufgelösten markierten,
zum ersten Analyten spezifischen Bindungspartner durch wenigstens die erste Zone des
chromatographischen Mediums, und Migrierenlassen des wiederaufgelösten, markierten,
zum zweiten Analyten spezifischen Bindungspartners durch wenigstens die zweite Zone
des zweiten chromatographischen Mediums, so daß ein erster Dreifachkomplex in der
ersten Zone des ersten chromatographischen Mediums gebildet wird, wenn der erste Analyt
in der Probe vorhanden ist, wobei der erste Dreifachkomplex den ersten Analyten, den
markierten, zum ersten Analyten spezifischen Bindungspartner, und den immobilisierten,
zum ersten Analyten spezifischen Bindungspartner umfaßt; und so daß ein zweiter Dreifachkomplex
in der zweiten Zone des zweiten chromatographischen Mediums gebildet wird, wenn der
zweite Analyt in der Probe vorhanden ist, wobei der zweite Dreifachkomplex den zweiten
Analyten, den markierten, zum zweiten Analyten spezifischen Bindungspartner, und das
immobilisierte Antigen zum zweiten Analyten umfaßt; und
(g) Feststellung des Vorhandenseins oder der Menge des ersten Analyten und des zweiten
Analyten in der wässrigen Probe durch Beobachtung und/oder Messung irgendeines erfaßbaren
Signals, das durch den markierten, zum ersten Analyten spezifischen Bindungspartner
erzeugt wird, der im ersten Dreifachkomplex in der ersten Zone im ersten chromatographischen
Medium gebunden ist, und irgendeines erfaßbaren Signals, das durch den markierten,
zum zweiten Analyten spezifischen Bindungspartner erzeugt wird, der im zweiten Dreifachkomplex
in der zweiten Zone des chromatographischen Mediums gebunden ist.
25. Verfahren nach Anspruch 24,
bei dem der markierte, für den ersten Analyten spezifische Bindungspartner, und der
markierte, zum zweiten Analyten spezifische Bindungspartner jeweils mit einer visuell
erfaßbaren Markierung markiert sind und der Schritt der Beobachtung und/ oder Messung
des erfaßbaren Signals visuell durchgeführt wird.
1. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant au moins un milieu chromatographique
ayant (1) une première extrémité comprenant une zone conjuguée imprégnée d'un partenaire
de liaison spécifique marqué au premier analyte, (2) une première zone intermédiaire
comprenant un partenaire de liaison spécifique immobilisé au premier analyte et (3)
une seconde extrémité ayant une seconde zone comprenant un antigène immobilisé qui
se lie spécifiquement au second analyte ;
(b) un second composant opposable ayant un absorbeur qui est mis en communication
de fluide avec une aire du au moins un milieu chromatographique entre ses première
et seconde zones quand les premier et second composants opposables sont mis en contact
physique ; et
(c) un partenaire de liaison spécifique marqué au un second analyte imprégné soit
dans le premier ou le second composant opposable dans une zone en communication de
fluide en aval avec la seconde zone ;
où les premier et second composants opposables peuvent être mis en contact physique
pour produire un essai de liaison spécifique chromatographique unidirectionnel pour
le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur au premier composant
opposable après migration d'un échantillon aqueux appliqué de la première extrémité
à la seconde extrémité du premier composant opposable afin d'inverser la direction
de l'écoulement du fluide entre les première et seconde extrémités, et détection des
premier et second analytes par détection de la formation de complexes ternaires marqués
dans une première et une seconde zone respectivement.
2. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant au moins un milieu chromatographique
ayant (1) une première extrémité, (2) une première zone intermédiaire comprenant un
partenaire de liaison spécifique immobilisé au premier analyte et (3) une seconde
extrémité ayant une seconde zone comprenant un antigène immobilisé qui se lie spécifiquement
au second analyte ; et
(b) un second composant opposable ayant (1) un premier applicateur imprégné du partenaire
de liaison spécifique marqué pour le premier analyte qui est porté en communication
de fluide avec la première zone quand les premier et second composants opposables
sont mis en contact physique, (2) un absorbeur qui est mis en communication de fluide
avec une aire du au moins un milieu chromatographique entre les première et seconde
zones de celui-ci, quand les premier et second composants opposables sont mis en contact
physique et (3) un second applicateur imprégné d'un partenaire de liaison spécifique
marqué pour le second analyte, qui est mis en communication de fluide avec la seconde
zone quand les premier et second composants opposables sont mis en contact physique
;
où les premier et second composants opposables peuvent être mis en contact physique
pour produire un essai de liaison spécifique chromatographique unidirectionnel pour
le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur avec le premier
composant opposable après migration d'un échantillon aqueux appliqué de la première
extrémité à la seconde extrémité du premier composant opposable afin d'inverser la
direction de l'écoulement de fluide entre les première et seconde extrémités, et détection
des premier et second analytes par détection de la formation de complexes ternaires
marqués dans les première et seconde zones, respectivement.
3. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant au moins un milieu chromatographique
ayant (1) une première extrémité comprenant un premier applicateur imprégné d'un partenaire
de liaison spécifique marqué au premier analyte, (2) une première zone intermédiaire
comprenant un partenaire de liaison spécifique immobilisé au premier analyte et (3)
une seconde extrémité ayant une seconde zone comprenant un antigène immobilisé qui
se lie spécifiquement au second analyte ; et
(b) un second composant opposable ayant (1) un absorbeur qui est mis en communication
de fluide avec une aire du au moins un milieu chromatographique entre ses première
et seconde zones quand les premier et second composants opposables sont mis en contact
physique et (2) un second applicateur imprégné d'un partenaire de liaison spécifique
marqué pour le second analyte qui est mis en communication de fluide avec la seconde
zone quand les premier et second composants opposables sont mis en contact physique
;
où les premier et second composants opposables peuvent être mis en contact physique
pour produire un essai de liaison spécifique chromatographique unidirectionnel pour
le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur au premier composant
opposable après migration d'un échantillon aqueux appliqué par le premier applicateur
à la seconde extrémité du premier composant opposable afin d'inverser la direction
de l'écoulement de fluide entre les première et seconde extrémités, et détection des
premier et second analytes par détection de la formation de complexes ternaires marqués
dans les première et seconde zones, respectivement ; et où l'absorbeur exclut sensiblement
le partenaire de liaison spécifique marqué au second analyte de la première zone en
bloquant le partenaire de liaison spécifique marqué au second analyte contre toute
migration dans la première zone.
4. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant :
(i) au moins un milieu chromatographique ayant (1) une première extrémité, (2) une
première zone intermédiaire comprenant un partenaire de liaison spécifique immobilisé
au premier analyte et (3) une seconde extrémité ayant une seconde zone comprenant
un antigène immobilise qui se lie spécifiquement au second analyte ; et
(ii) une zone de préparation de l'échantillon placée entre la première et la seconde
zone ; et
(b) un second composant opposable ayant (1) un premier applicateur imprégné d'un partenaire
de liaison spécifique marqué pour le premier analyte qui est mis en communication
de fluide avec la première zone quand les premier et second composants opposables
sont mis en contact physique, (2) un absorbeur qui est mis en communication de fluide
avec une aire du au moins un milieu chromatographique entre les première et seconde
zones de celui-ci quand les premier et second composants opposables sont mis en contact
physique, et (3) un second applicateur imprégné d'un partenaire de liaison spécifique
marqué pour le second analyte qui est mis en communication de fluide avec la seconde
zone quand les premier et second composants opposables sont mis en contact physique
;
où les premier et second composants opposables peuvent être mis en contact physique
pour produire un essai de liaison spécifique chromatographique unidirectionnel pour
le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur au premier composant
opposable après migration d'un échantillon aqueux appliqué de la première extrémité
à la seconde extrémité du premier composant opposable afin d'inverser la direction
de l'écoulement du fluide entre les première et seconde extrémités, et détection des
premier et second analytes par détection de la formation de complexes ternaires marqués
dans les première et seconde zones, respectivement ; et où la mise en contact physique
de l'absorbeur sépare la première zone de la seconde zone, donc le partenaire de liaison
spécifique marqué au second analyte est sensiblement exclu de la première zone en
bloquant le partenaire de liaison spécifique marqué au second analyte pour l'empêcher
de s'écouler dans la première zone.
5. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant au moins un milieu chromatrographique
ayant, dans l'ordre de communication de fluide (1) une première extrémité, (2) un
premier applicateur, (3) une zone conjuguée imprégnée d'un partenaire de liaison spécifique
marqué au premier analyte reliant la première extrémité et le premier applicateur,
(4) une première zone comprenant un partenaire de liaison spécifique immobilisé au
premier analyte, (5) une seconde zone comprenant un antigène immobilisé qui se lit
spécifiquement au second analyte, (6) un conducteur de fluide, et (7) une seconde
extrémité ; et
(b) un second composant opposable comprenant :
(i) un absorbeur qui est mis en communication de fluide avec une zone du au moins
un milieu chromatographique entre les première et seconde zones de celui-ci quand
les premier et second composants opposables sont mis en contact physique ; et
(ii) un second applicateur imprégné d'un partenaire de liaison spécifique marqué pour
le second analyte qui est mis en communication de fluide avec le conducteur de fluide
quand les premier et second composants opposables sont mis en contact physique ; où
les premier et second composants opposables peuvent être mis en contact physique pour
produire un essai de liaison spécifique chromatographique unidirectionnel pour le
premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur avec le premier
composant opposable après migration d'un échantillon aqueux appliqué de la première
extrémité à la seconde extrémité du premier composant opposable afin d'inverser la
direction de l'écoulement du fluide entre les première et seconde extrémités et détection
des premier et second analytes par détection de la formation de complexes ternaires
marqués dans les première et seconde zones, respectivement.
6. Dispositif d'essai de la revendication 5 où le second analyte est un anticorps produit
par une espèce mammalienne en réponse à un antigène, où l'antigène est le même que
l'antigène immobilisé et le partenaire de liaison spécifique marqué est un anticorps
marqué qui se lit spécifiquement au second analyte par liaison à la région constante
du second analyte.
7. Dispositif d'essai de la revendication 6 où l'anticorps marqué lie le second analyte
par liaison à un déterminant spécifique de l'espèce.
8. Dispositif d'essai de la revendication 5 où les première et seconde zones du au moins
un milieu chromatographique sont de porosités différentes.
9. Dispositif d'essai de la revendication 8 où le au moins un milieu chromatographique
est de la nitrocellulose.
10. Méthode pour déterminer la présence ou la quantité d'au moins deux analytes dans un
échantillon aqueux, comprenant les étapes séquentielles de :
(a) appliquer une première aliquote de l'échantillon au premier applicateur du dispositif
d'essai de la revendication 5 ;
(b) laisser l'échantillon migrer du premier applicateur à travers la zone conjuguée
puis à travers au moins le conducteur de fluide du au moins un milieu chromatographique
de manière qu'un premier complexe ternaire se forme dans la première zone si le premier
analyte est présent dans l'échantillon, le premier complexe ternaire comprenant le
premier analyte, le partenaire de liaison spécifique marqué au premier analyte et
le partenaire de liaison spécifique immobilisé au premier analyte ;
(c) porter les premier et second composants opposables en contact physique pour forcer
le second applicateur à venir en communication de fluide avec le au moins un milieu
chromatographique pour attirer du fluide du second applicateur à travers le conducteur
de fluide et à travers la seconde zone du au moins un milieu chromatographique, du
conducteur de fluide jusqu'à l'absorbeur, de manière qu'un second complexe ternaire
se forme dans la seconde zone si le second analyte est présent dans l'échantillon,
le second complexe ternaire comprenant le second analyte, le partenaire de liaison
spécifique marqué au second analyte et l'antigène immobilisé au second analyte ; et
(d) déterminer la présence ou la quantité des au moins deux analytes dans l'échantillon
aqueux en observant et/ou en mesurant tout signal détectable produit par le partenaire
de liaison spécifique marqué au premier analyte lié dans le premier complexe ternaire
dans la première zone et tout signal détectable produit par le partenaire de liaison
spécifique marqué au second analyte lié dans le second complexe ternaire dans la seconde
zone.
11. Méthode de la revendication 10 où chacun du partenaire de liaison spécifique marqué
au premier analyte et du partenaire de liaison spécifique marqué au second analyte
est marqué avec un marqeur détectable et l'étape d'observer et/ou de mesurer les signaux
détectables est accomplie visuellement.
12. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant au moins un milieu chromatographique
ayant, en ordre de communication de fluide (1), unre première extrémité, (2) un premier
conducteur de fluide, (3) une zone de préparation de l'échantillon, (4) une première
zone comprenant un partenaire de liaison spécifique immobilisé au premier analyte,
(5) une seconde zone comprenant un antigène immobilisé qui se lie spécifiquement au
second analyte, (6) un second conducteur de fluide et (7) une seconde extrémité ;
et
(b) un second composant opposable comprenant :
(i) un premier applicateur imprégné d'un partenaire de liaison spécifique marqué resolubilisable
pour le premier analyte qui est mis en communication de fluide avec le premier conducteur
de fluide quand les premier et second composants opposables sont mis en contact physique
;
(ii) un absorbeur qui est mis en communication de fluide avec la zone de préparation
de l'échantillon du au moins un milieu chromatographique quand les premier et second
composants opposables sont mis en contact physique ; et
(iii) un second applicateur imprégné d'un partenaire de liaison spécifique marqué
resolubilisable pour le second analyte qui est mis en communication de fluide avec
le second conducteur de fluide quand les premier et second composants opposables sont
mis en contact physique ;
où les premier et second composants opposables sont capables d'être mis en contact
physique pour produire un essai de liaison spécifique chromatographique unidirectionnel
pour le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte par mise en contact physique de l'absorbeur avec le premier
composant opposable après migration d'un échantillon aqueux appliqué de la première
extrémité à la seconde extrémité du premier composant opposable afin d'inverser la
direction de l'écoulement du fluide entre les première et seconde extrémités et détection
des premier et second analytes par détection de la formation de complexes ternaires
marqués dans les première et seconde zones, respectivement.
13. Dispositif d'essai de la revendication 12 où le second analyte est un anticorps produit
par une espèce mammalienne en réponse à un antigène, où l'antigène est le même que
l'antigène immobilisé et le partenaire de liaison spécifique marqué est un anticorps
marqué qui se lie spécifiquement au second analyte par liaison à la région constante
du second analyte.
14. Dispositif d'essai de la revendication 13 où l'anticorps marqué lie le second analyte
par liaison à un déterminant spécifique de l'espèce.
15. Dispositif d'essai de la revendication 12 où les première et seconde zones du au moins
à un milieu chromatographique sont de porosités différentes.
16. Dispositif d'essai de la revendication 15 où le au moins un milieu chromatographique
est de la nitrocellulose.
17. Méthode pour déterminer la présence ou la quantité d'au moins deux analytes dans un
échantillon aqueux, comprenant les étapes séquentielles de :
(a) appliquer un premier liquide aqueux au second applicateur du dispositif d'essai
de la revendication 12 pour resolubiliser le partenaire de liaison spécifique marqué
au second analyte ;
(b) appliquer une première aliquote de l'échantillon au premier applicateur pour resolubiliser
le partenaire de liaison spécifique marqué au premier analyte ;
(c) appliquer une seconde aliquote de l'échantillon à la zone de préparation de l'échantillon
;
(d) permettre à la seconde aliquote de l'échantillon appliqué à la zone de préparation
de l'échantillon de migrer à travers au moins le second conducteur de fluide du au
moins un milieu chromatographique ;
(e) porter les premier et second composants opposables en contact physique pour forcer
l'absorbeur à venir en contact avec le au moins un milieu chromatographique, le premier
applicateur à venir en contact avec le premier conducteur de fluide et le second applicateur
à venir en contact avec le second conducteur de fluide ;
(f) permettre à la première aliquote de l'échantillon et au partenaire de liaison
spécifique marqué resolubilisé au premier analyte de migrer à travers au moins la
première zone du au moins un milieu chromatographique de façon qu'un premier complexe
ternaire se forme dans la première zone si le premier analyte est présent dans l'échantillon,
le premier complexe ternaire comprenant le premier analyte, le partenaire de liaison
spécifique marqué au premier analyte et le partenaire de liaison spécifique immobilisé
au premier analyte ; et permettre au partenaire de liaison spécifique marqué resolubilisé
au second analyte de migrer à travers au moins la seconde zone du au moins un milieu
chromatographique de manière qu'un second complexe ternaire soit formé dans la seconde
zone si le second analyte est présent dans l'échantillon, le second complexe ternaire
comprenant le second analyte, le partenaire de liaison spécifique marqué au second
analyte et l'antigène immobilisé au second analyte ; et
(g) déterminer la présence et la quantité du premier analyte et du second analyte
dans l'échantillon aqueux en observant et/ou en mesurant tout signal détectable produit
par le partenaire de liaison spécifique marqué au premier analyte lié dans le premier
complexe ternaire dans la première zone et tout signal détectable produit par le partenaire
de liaison spécifique marqué au second analyte lié dans le second complexe ternaire
dans la seconde zone.
18. Méthode de la revendication 17 où le partenaire de liaison spécifique marqué pour
le premier analyte et le partenaire de liaison spécifique marqué pour le second analyte
sont marqués avec un marqueur visuellement détectable et l'étape d'observer et/ou
de mesurer les signaux détectables est accomplie visuellement.
19. Dispositif d'essai pour détecter au moins deux analytes dans un échantillon aqueux,
un premier analyte qui est un antigène et un second analyte qui est un anticorps,
le dispositif d'essai comprenant :
(a) un premier composant opposable comprenant :
(i) un premier milieu chromatographique ayant, dans l'ordre de communication de fluide
(1) une première extrémité, (2) un premier conducteur de fluide, (3) une première
zone comprenant un partenaire de liaison spécifique immobilisé au premier analyte,
et (4) une seconde extrémité ; et
(ii) un second milieu chromatographique ayant, dans l'ordre de communication de fluide,
(1) une première extrémité, (2) une zone de préparation de l'échantillon, (3) une
seconde zone comprenant un antigène immobilisé qui se lie spécifiquement au second
analyte, (4) un second conducteur de fluide et (5) une seconde extrémité ;
(b) un second composant opposable comprenant :
(i) un premier applicateur imprégné d'un partenaire de liaison spécifique marqué resolubilisé
pour le premier analyte qui est mis en communication de fluide avec le premier conducteur
de fluide quand les premier et second composants opposables sont mis en contact physique
;
(ii) un absorbeur qui est mis en communication de fluide avec la zone de préparation
de l'échantillon et avec le premier milieu chromatographique quand les premier et
second composants opposables sont mis en contact physique ; et
(iii) un second applicateur imprégé d'un partenaire de liaison spécifique marqué resolubilisé
pour le second analyte qui est mis en communication de fluide avec le second conducteur
de fluide, quand les premier et second composants opposables sont mis en contact physique
;
où les premier et second composants opposables peuvent être mis en contact physique
pour produire un essai de liaison spécifique chromatographique unidirectionnel pour
le premier analyte et un essai de liaison spécifique chromatographique bidirectionnel
pour le second analyte, par mise en contact physique de l'absorbeur au premier composant
composable après migration d'un échantillon aqueux appliqué de la première extrémité
à la seconde extrémité du premier composant opposable afin d'inverser la direction
de l'écoulement de fluide entre les première et seconde extrémités et détection des
premier et second analytes par détection de la formation de complexes ternaires marqués
dans les première et second zones, respectivement.
20. Dispositif d'essai de la revendication 19 où le second analyte est un anticorps produit
par une espèce mammalienne en réponse à un antigène, où l'antigène est le même que
l'antigène immobilisé et le partenaire de liaison spécifique marqué est un anticorps
marqué qui se lie spécifiquement au second analyte par liaison à la région constante
du second analyte.
21. Dispositif d'essai de la revendication 20 où l'anticorps marqué se lie au second analyte
par liaison à un déterminant spécifique de l'espèce.
22. Dispositif d'essai de la revendication 19 où les premier et second milieux chromatographiques
sont de porosités différentes.
23. Dispositif d'essai de la revendication 22 où les premier et second milieux chromatographiques
sont de la nitrocellulose.
24. Méthode pour déterminer la présence ou la quantité d'au moins deux analytes simultanément
dans un échantillon aqueux, comprenant les étapes séquentielles de :
(a) appliquer un premier liquide aqueux au second applicateur du dispositif d'essai
de la revendication 19 pour resolubiliser le partenaire de liaison spécifique marqué
au second analyte ;
(b) appliquer une première aliquote de l'échantillon au premier applicateur du dispositif
d'essai pour resolubiliser le partenaire de liaison spécifique marqué au premier analyte
;
(c) appliquer une seconde aliquote de l'échantillon à la zone de préparation de l'échantillon
;
(d) permettre à la seconde aliquote de l'échantillon appliquée à la zone de préparation
de l'échantillon de migrer à travers au moins le second conducteur de fluide du second
milieu chromatographique ;
(e) mettre les premier et second composants opposables en contact physique pour forcer
l'absorbeur à venir en contact avec la zone de préparation de l'échantillon et le
premier milieu chromatographique, pour forcer le premier applicateur à venir en contact
avec le premier conducteur de fluide et pour forcer le second applicateur à venir
en contact avec le second conducteur de fluide ;
(f) permettre à la première aliquote de l'échantillon et au partenaire de liaison
spécifique marqué resolubilisé au premier analyte de migrer à travers au moins la
première zone du milieu chromatographique et permettre au partenaire de liaison spécifique
marqué resolubilisé au second analyte de migrer à travers au moins la seconde zone
du second milieu chromatographique de manière qu'un premier complexe ternaire se forme
dans la première zone du premier milieu chromatographique si le premier analyte est
présent dans l'échantillon, le premier complexe ternaire comprenant le premier analyte,
le partenaire de liaison spécifique marqué au premier analyte et le partenaire de
liaison spécifique immobilisé au premier analyte ; et de façon qu'un second complexe
ternaire se forme dans la seconde zone du second milieu chromatographique si le second
analyte est présent dans l'échantillon, le second complex ternaire comprenant le second
analyte, le partenaire de liaison spécifique marqué au second analyte et l'antigène
immobilisé au second analyte ; et
(g) déterminer la présence ou la quantité du premier analyte et du second analyte
dans l'échantillon aqueux en observant et/ou en mesurant tout signal détectable produit
par le partenaire de liaison spécifique marqué au premier analyte lié dans le premier
complexe ternaire dans la première zone dans le premier milieu chromatographique et
tout signal détectable produit par le partenaire de liaison spécifique marqué au second
analyte lié dans le second complexe ternaire dans la seconde zone du milieu chromatographique.
25. Méthode de la revendication 24 où le partenaire de liaison spécifique marqué au premier
analyte et le partenaire de liaison spécifique marqué au second analyte sont marqués
d'un marqueur visuellement détectable et l'étape d'observer et/ou de mesurer les signaux
détectables est accomplie visuellement.